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      The Epidemiology of Circulating Rotavirus Associated with Diarrhea in Egyptian Kids and Calves: A Review

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            Abstract

            Acute gastroenteritis (AGE) induced by rotavirus has been a major disease burden in Egypt since 1981 when rotavirus was first reported in humans and calves. Genome segmentation facilitates the emergence of new virus serotypes, which allows reassortment during mixed infections, and is a characteristic feature of the family Reoviridae to which rotavirus belongs. The rotavirus genome involves 11 double-stranded RNA gene segments encoding 6 non-structural (NSP1–6) and 6 structural (VP1–4, VP6, VP7) proteins. Rotavirus A has a zoonotic potential associated with diarrhea. The primary strategy for prevention and control of bovine and human rotavirus infections is vaccination; however, routine rotavirus vaccination has not been implemented in the National Immunization Program. We evaluated studies published over the last 30 years that pertained to the epidemiology of circulating rotavirus genotypes among children, calves, and environmental samples in Egypt. The analysis revealed a rotavirus prevalence of 15%–100%, with diarrhea occurring throughout the year, but generally peaking during the cold months. G1 was the predominant genotype in children, followed by G2, G3, G4, G8, G9, and G12 throughout the study duration. Mixed infections were also detected. G6 was the predominant genotype in calves, followed by G10. There are still gaps in knowledge regarding molecular data of rotavirus infections in humans, animals, and environmental samples in Egypt, as well as the zoonotic potential of rotavirus disease. Therefore, it is critical to continue rotavirus surveillance in Egypt to further understand the epidemiology of rotavirus infections and the emerging new genotypes.

            Main article text

            INTRODUCTION

            Acute diarrheal disease (ADD) or gastroenteritis is a disease caused by bacteria, viruses, and parasites, and is characterized by increased bowel motility, which causes watery or loose stools [1]. ADD is the most common disease globally and the principal cause of death among children <5 years of age [2]. Indeed, most children <5 years of age worldwide have had gastroenteritis [3]. Moreover, the number of children <5 years of age worldwide with infectious diarrhea caused by rotavirus (RV) infection has been estimated to be approximately 258 million [4]. Between 2013 and 2017, RV induced 122,000–215,000 diarrheic child deaths annually [46]. RV ranks third among leading pathogens associated with mortality among all causes of death in children <5 years of age [6]. Children in low- and medium-income countries (LMICs) represent the majority of diarrheal deaths compared to high-income countries (HICs) [4]. A worldwide health-related statistic from 2016 revealed that among 10 developing countries, approximately 100/100,000 children die before reaching 5 years of age, representing the highest RV diarrheic deaths [5]. Currently, live attenuated oral RVs are used as the main strategy to control RV diseases, especially in countries with high mortality rates [7]. World Health Organization (WHO) approved two RV vaccines (RotaTeq [RV5] and Rotarix [RV1]) in 2008 and 2009, respectively, that are the most extensively used vaccines worldwide for the prevention of RV infection [7]. Although the WHO recommended the inclusion of RV vaccines into all national immunization programs, more than 100 countries, including Egypt, have not introduced the vaccines into their compulsory immunization program [8]. Thus, it is important to continuously survey rotavirus genotypes to verify if the oral vaccines provide full protection against the common RV genotypes infecting Egyptian children. This information is crucial to enhance vaccine development, detect emerging genotypes, and aid in the evaluation of vaccine efficacy and changes in strain diversity after vaccines have been introduced.

            Gastroenteritis in animals is caused mainly by RV that was isolated from numerous species of domesticated and wild mammals [9,10], as well as birds [11]. Subsequently, these infections significantly led to economic losses in different livestock (cattle, swine, and horses) due to the weight loss of affected animals and the cost of treatment. There is increasing proof of interspecies transmission and reassortment between human and animal RVs. Some species, such as cattle, pigs, dogs, and cats, have already been shown to share the RV genetic diversity detected in humans [12]. Neonatal calf diarrhea is one of the most common diseases in the dairy industry, and is characterized by high morbidity and mortality [13]. Group A RVs are the main etiologic agents for calf diarrhea, which cause 5%–20% of calf losses [14].

            In 2010 the WHO estimated that 1.8 billion people drink unsafe water and 1.2 billion people drink contaminated water. In fact, 700,000 diarrheal deaths globally are attributable to contaminated water each year [15]. Urban wastewater discharged into surface water can act as a source of environmental viral contamination. Contamination of the environment can also occur from the reuse of wastewater for agriculture or industrial purposes. Enteric viruses are major causes of gastroenteritis [16] and frequently replicate in the gastrointestinal tract. Enteric viruses are excreted in human feces, in which an infected person can shed up to 105–1013 viral particles/g [17,18]. Enteric viruses have been found not only in wastewater, but also in rivers, recreational water, and seawater, as well as ground water and even treated drinking water [19]. Symptomatic and asymptomatic persons shed a huge number of viruses into the sanitary network each day. Therefore, wastewater is one of the major concentrated sources of human enteric viruses in the environment. Moreover, if the sanitary network is broken, or untreated or partially treated wastewater is released directly into the environment, pollution of other environmental water sources (groundwater, rivers, and pond water) may occur [20]. Sporadic cases and outbreaks of gastroenteritis have been detected in association with RV, norovirus, astrovirus, and adenovirus, which are also important agents of water-related diseases [17].

            Herein, the epidemiology of RV disease is highlighted and the prevalence of G and P RV serotypes is analyzed on the basis of data collected from PubMed or other local databases focusing on children with RV-related diarrhea, calves with diarrhea, and environmental samples in Egypt between 1992 and 2022. The possibility of interspecies transmission and reassortment of RV between human and animals are discussed.

            ROTAVIRUS STRUCTURE

            RV belongs to the Reoviridae family and is formed from a triple-layered particle (TLP) that consists of three types of particles (double-shelled, single-shelled, and core) arranged in concentric rings around the genome [21]. The TLP is the infectious form of the virus [22]. The diameters of the double-shelled, single-shelled, and core particles are 76.5 nm, 70.5 nm, and 50 nm, respectively. RV is comprised of a double-stranded RNA (dsRNA) genome that is composed of 11 segments. Each segment encodes 1 of 6 structural viral proteins (VP1-4, VP6, and VP7) or 5-6 non-structural proteins (NSP1-5/6) [1,23]. The viral capsid proteins (VPs) are the major antigenic proteins of the RVs [24], while the NSPs are produced during infection to aid viral replication and pathogenesis [25].

            ROTAVIRUS GROUPS

            The RV gender includes viruses that only infect vertebrates (birds and mammals) [1]. The RVs have a common antigen (protein VP6), which forms the middle layer [26] (group antigen) [1]. RV can be classified based on VP6 into 10 groups (RVA-RVJ) according to the International Committee of Taxonomy of Viruses (ICTVs) [1,25,26]. RVK and RVL were also reported, but not included in the ICTVs [27]. RVA, RVB, RVC, and RVH infect humans and animals. Group B rotavirus has been identified in humans and some animal species (cattle, sheep, pigs, dogs, and rats). Group C RV affects pigs, cattle, humans, ferrets, and dogs [1]. RVH was first identified in humans in China and Bangladesh, more recently in pigs in Japan and Brazil [28,29]. RVD, RVE, RVF, and RVG have only been identified in animals [1,25]. RVD, RVF, and RVG only infect birds [1,30]. RVE has only been found in pigs [12]. Recently, RVI and RVJ were detected in dogs and bats, respectively [26,31].

            CLASSIFICATION OF GROUP A ROTAVIRUS

            RV classification is based on a binary classification system according to immunologic reactions and the structure of VP7 and VP4 protein genes into glycoprotein (G) and protease-sensitive (P) genotypes, respectively, which independently stimulate neutralizing antibody production [24,25]. Currently, 42 G-types and 58 P-types have been described according to the RV Classification Working Group based on global investigation reports in both humans and animals [32]. More recently, the whole genome or 11-gene typing system replaced the binary strain typing system to ascribe genotypes to each gene (Gx-P[x]-Ix-Rx-Cx-Mx-Ax-Nx-Tx-Ex-Hx), which codes for VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5/6, respectively [33]. The number of genotypes and the function of the encoded proteins are shown in Table 1 [34].

            TABLE 1 |

            Number of genotypes ascribed to each gene segment (updated) and the biological functions of the encoded proteins [33,34].

            Genome segmentSize (bp)Number of genotypesGenotype denotationProtein productType of protein/location in the virionFunction
            1330222RVP1Structural, inner capsid- RdRp
            - ssRNA binding
            2268720CVP2Structural, core- Houses RNA genome
            3259220MVP3Structural, inner capsidGuanyltransferase Methyltransferase
            ssRNA binding
            4236251PVP4Structural, outer capsid- Receptor binding protein
            - Infectivity enhancement through trypsin cleavage
            5135626IVP6Structural, middle capsidSerologic grouping and subgrouping antigen
            6106236GVP7Structural, outer capsid- Neutralization antigen
            - Basis of binary classification
            7158131ANSP1Non-structural- Host interferon antagonist
            - Anti-apoptosis
            8105922NNSP2Non-structural- Helicase
            - NTPase
            - NDPK
            - RBP
            9107422TNSP3Non-structural- Competition with host PABP for self-4G1 binding
            - Translation enhancer
            1075127ENSP4Non-structural- Enterotoxin
            - Transmembrane gp
            1166622HNSP5Non-structural- Phosphoprotein
            NSP6Non-structural- ssRNA and dsRNA binding

            Note: RdRp = RNA-dependent RNA polymerase; PABP = poly (A) binding protein; RBP = RNA binding protein; NDPK = nucleoside diphosphate kinase.

            ROTAVIRUS DETECTION AND STRAIN CHARACTERIZATION

            Fresh stool samples or rectal swabs are the main samples used to detect RV infection by confirming the presence of the RV, virus-specific antigen, or RNA [35,36]. The laboratory diagnosis of RV includes several techniques, such as electron microscopy (EM) [37], which recognizes and identifies the virus depending on morphologic characteristics; however, this technique is expensive, needs well-trained workers, and a large number of persons for the routine diagnosis of RV in a large number of specimens. Also, many commercially-available antigen detection kits, such as ELISA, latex agglutination, or immunochromatography, are used to diagnose RV. The latex agglutination technique is simple, quick, and easy to perform without the need of complicated equipment. Therefore, the latex agglutination technique is useful in disease outbreak detection [38]. ELISA is the most widely used antigen detection method because of high sensitivity, specificity, and ability to test large number of samples in 96-well plates [35,36]. Virus isolation and growth in cell lines is a useful technique to confirm virus viability and enhance molecular detection of the virus, especially if the virus is in very low concentration in environmental or clinical samples [3941]. Although viral isolation from cell lines is highly sensitive, this method is expensive, difficult, easily contaminated, and often not required for routine clinical diagnosis. Different types of polymerase chain reactions (PCRs), such as reverse transcription (RT-PCR), quantitative (q)PCR, and real-time PCR, detect RNA in clinical or environmental samples and are more sensitive techniques than other antigen detection methods [35,42,43]. For genotyping of circulating RV strains, VP4 and VP7 sequences, and other genome segments are required. More recently, the RV Classification Working Groups recommend whole genome sequencing for complete characterization of the RV genome and recognition of unusual genotypes [44].

            MODE OF TRANSMISSION

            RV is mainly transmitted via the fecal-oral route [45]. As shown in Fig 1, the spread of human feces is often enhanced by environmental factors, cush as fingers, foods, fluids, and fomites through interactions between humans or animals with the environment [46]. The spread of RV is common among children; moreover, transmission to close contacts is highly likely from infected children. RV has the ability of interspecies and cross-species transmission; reassortments occur, which are the main mechanisms that cause diversity of RVs and the emergence of new strains [47].

            FIGURE 1 |

            The figure shows the mode of rotavirus transmission. The primary mode of transmission is the transfer of the virus in the stool of one child-to-the mouth of another child (fecal-oral route). Other possible means of transmission are contaminated food, contaminated water, and fomites. The vertical lines (black) show barriers against transmission, i.e., toilet barrier, clean water barrier, hand washing, and proper hygiene barrier [21].

            CLINICAL FEATURES

            Neonates (<1 month of age) often have asymptomatic or mildly symptomatic RV infection due to protection provided by maternal antibodies transferred via the placenta and breast milk [48]. The clinical symptoms of RV infection include the following: no symptoms-to-mild symptoms; and watery diarrhea of short duration-to-severe diarrhea with vomiting and fever that can cause rapid dehydration with shock, electrolyte imbalance, and death [24]. The incubation period of RV is 18–36 h and is followed by the onset of acute fever and vomiting [49]. In children, more than one episode of RV infection may occur due to the inability of the natural infection or the vaccine to provide full protection against future infections. Remarkably, the primary infection induces more severe signs than recurrent infections [50].

            RV diarrhea in calves is an acute infection with a very short incubation period of 12–24 h that ranges from 18–96 h. RV in calves is characterized by high morbidity, although infection is usually mild and self-limiting. The clinical symptoms in calves are affected by host age, host immune status, host nutrition status, environmental stress (such as housing, overcrowding or weather conditions), variation in virulence among RV strains, and occurrence of mixed infections. The clinical features of RV infection in calves involve fluid loss and metabolic acidemia, anorexia, profuse watery diarrhea, and different degrees of systemic dehydration [51]. In severe cases, death occurs as a consequence of electrolyte imbalances, dehydration, and cardiac arrest [52].

            DISTRIBUTION OF GROUP A ROTAVIRUS STRAINS IN EGYPTIAN CHILDREN

            Genotyping of RVA strains in epidemiologic investigations is determined by G and P types. Due to the segmented characteristic of the RVA genome, the genes that encode for VP7 and VP4 can segregate in an independent manner, leading to a large diversity of strains. Over the last 30 years, RV epidemiologic studies have been conducted in both urban and rural areas in Egypt. Between 1992 and 2008, a total of 5804 samples from children were subjected to RV detection and genotyping, of which 671 (11.5%) were positive. G1 was the most predominant genotype, followed by G2, then G3 and G9; G4, G8, and G12 were also detected during this period. Between 2008 and 2022, a total of 2552 samples were subjected to RV detection and genotyping, of which 829 (32.5%) were positive. G1 remained the predominant genotype, followed by G3, then G9, G2, G4, G8, and G12. These studies were carried out on patients with acute diarrhea from outpatient clinic visits or hospitalizations. These studies showed an average RV prevalence of 15%–100%. Data are shown in Figs 2 and 3, and Table 2.

            FIGURE 2 |

            A; Distribution of G genotypes in samples (n=1500) collected from children between 1992 and 2022 in Egypt. B; G genotypes in children between 1992 and 2008 (n=671) in Egypt. C; G genotypes in children between 2008 and 2022 (n=829) in Egypt.

            FIGURE 3 |

            A; Distribution of P genotypes in samples (n=1500) collected from children between 1992 and 2022 in Egypt. B; P genotypes in children between 1992 and 2008 (n=671) in Egypt. C; P genotypes in children between 2009 and 2022 (n=829) in Egypt.

            TABLE 2 |

            Rotavirus genotypes among Egyptian children with acute gastroenteritis.

            Area of studyYear of studyNumber of stool samples testedAge (years)Percent positive with rotavirusPredominant G genotypePredominant P genotypeReference
            Cairo University Children’s HospitalAugust 1992 and October 1993180<1 year35.60%G1 and G4Not typed[53]
            Abu Homos, EgyptFebruary 11, 1995–February 10, 1996178<3 years25.80%G2P[4][54]
            Abu Homos, Egypt1995-1996217 and 30 months100%G8P[14][55]
            Abu homos District Hospital and Banha Fever UniversityMay 2000–May 20021026<5 years25.2%G1P[8][56]
            Abu Homos District Hospital20041<5 years100%G6P[14][57]
            Abu Homos, EgyptJanuary 2004–April 20074001Birth-2 years5.60%G2Not typed[58]
            Assiut Pediatric University HospitalDecember 2005–April 200688<3 years50%G3Not typed[59]
            Alexandria University Children's HospitalJanuary 2006–December 2006100<5 years33%G4Not typed[60]
            Tabarak Hospital Cairo, dispensaries in GizaMarch 2006–February 20072301 month-18 years33%G2P[4][61]
            Abu-El Rish hospitals, Cairo, EgyptFebruary 2009–January 2010100<4 years19%G1P[4] and P[8][62]
            Cairo (El-Demerdash Hospital) [200/450]
            Fayoum (Fayoum General Hospital) [150/450]
            Sharkia Governorate (Belbes General Hospital) [100/450]
            May 2009–April 2010450Infants and children <5 years35%G1Not typed[63]
            Mansoura University Children’s HospitalSeptember 2010–February 201292<3 years48.90%G1P[8][64]
            Cairo University Children Hospital, Al-Saff Children ClinicAugust 2011–August 20121972 years of age with acute diarrhea39.10%G3P[8][65]
            Abu-El Rish Hospital, Cairo, EgyptMay 2015–April 2016198 stool specimens<5 years28.30%G3Not typed[66]
            Abou El-reesh Children’s Hospital of Pediatrics in CairoJune 2015–May 2016119 fecal diarrhea<5 years31%G1P[8][67]
            Abo El-Reech Hospital, in Greater Cairo, EgyptOctober 2015–September 20171026 stool specimens<5 years24.37%G1P[4][68]
            Hospitals and Special Clinics from Qalubia and Cairo Governorates, EgyptApril 2018–June 201970 stool specimensNot mentioned35.70%G1P[8][69]
            Abo El-Reesh and El-DemerdashDecember 2018–April 2020230Birth-5 years14.80%G1Not typed[70]
            Children Hospital, Zagazig UniversityJanuary 2019–January 2020140 stool specimens1 month-5 years91.40%G3P[8][71]
            G1–G4 genotypes

            All 4 globally-important RV G types (G1–G4) of epidemiologic significance have been detected in Egypt. Each genotype was predominant over a specific time period. The first study genotyping human RV, which was conducted in Egypt in 1992, revealed that G1 and G4 were equally predominant genotypes [53]; however, other reports have revealed that the G1 genotype was mostly predominant in 2002 [56], between 2009 and 2012 [6264], 2015–2017 [67,68], and 2018–2020 [69,70]. The G2 genotype was the most predominant genotype during the 1995–1996, 2004–2007, and 2006–2007 seasons [54,58,61]. Other studies indicated that the G3 genotype was predominant during the 2005–2006, 2011–2012, 2015–2016, and 2019–2020 seasons [59,65,66,71]. G4 was the predominant strain during the 1992–1993 season [53] and in 2006 [60].

            P[8], P[4], and P[6] genotypes

            P[8], P[4], and P[6] are the major P genotypes, accounting for nearly 99% of all human RV infections occurring in Egypt. P[8] was the most prevalent genotype in 2002 and between 2009 and the present studies reported that P[8] represented >50% of all P genotypes detected in many regions of Egypt during the study period [56,62,64,65,67,6971]; P[4] and P[6] were the second and third most common P genotypes identified, respectively [56,61,64,6669]. Other investigations reported that the P[4] genotype was predominant during February 1995 through February 1996 in Abu Homos district, March 2006 through February 2007 in Cairo and Giza governorates, Feb. 2009 to Jan. 2010 and Oct. 2015 to Sep. 2017 in Cairo [54,61,62,68].

            CLINICAL SIGNIFICANCE OF UNUSUAL G GENOTYPES IN EGYPT

            G9 genotype

            G9 is known to be the fifth most common genotype, after the G1–G4 genotypes, currently circulating in the human population. The first G9 rotavirus, WI61, was identified in children in the USA in 1983 [72]. Subsequently, G9 strains have been commonly described as the causative agents of diarrhea among children and have been identified in several countries as one of the most widespread and emerging genotypes [73]. In Egypt, the G9 strain was first identified during the 2000–2001 rotavirus season [60]. Subsequently, G9 strains have been identified during successive seasons across the country [56,58,6169].

            G12 genotype

            G12 was first detected in1987 in the Philippines and was designated L26. The G12 genotype was first identified in Egypt during the 2006–2007 season [61]. Another study detected the G12 genotype during the 2011–2012 season [65].

            G10 genotype

            Research analyses showed that the G10 RV strain has seldom been identified in Egypt. Only one G10 strain has been detected in Egypt, and this occurred during the 2015–2016 season [66]; however, more studies are warranted to determine the importance and distribution of this RV strain in the Egyptian population.

            HUMAN ROTAVIRUS MIXED INFECTIONS

            Mixed and multiple RV infections have been recorded in Egypt. The first RV mixed infection involving G1 and G2 was recorded in 1992 [54]. Another study [58] reported the first co-infection involving G2 and G3, and G2 and G9. Amer et al. [60] detected the first mixed RV infection involving G1 and G9. A mixed infection involving G1and G4 was also recorded during the 2009–2010 season [63]. A previous study described a mixed infection involving G1 and G3 [65]. Another study detected mixed infections involving G1 and G9, and G1 and G4 [64]. Multiple infections involving G1/G3/G8, and G3/G8 were described for the first time in Egypt during the 2015–2016 season [66].

            SEASONAL VARIATION OF ROTAVIRUS IN HUMANS

            RV infections occur in Egypt throughout the year. Most studies have shown that peak infections mainly occur in the winter [6063,65,68,70]. Saudy et al. [64] and Ahmed et al. [58] reported peak RV infections in autumn. Allayeh et al. [67] and Shaheen et al [66] showed that peak RV infections occurred in the spring.

            DISTRIBUTION OF ROTAVIRUS STRAINS IN ANIMALS

            G6, G10, and G8 combined with P[5], P[11], and P[1] are considered to be important bovine RV-group A genotypes [74]. Bovine RV was first detected in Egypt in 1981 [75]. Since that time, numerous studies have been conducted that detected RV in cattle calves [7682]. Only two studies genotyped circulating bovine RV strains in Egypt, in which G6 was the predominant genotype followed by G10; however, P[5] was the predominant serotype followed by P[11] with the detection of only one mixed infection involving P[5] and P[11] [83,84]. Hemida [85] confirmed the first group D avian RV in Egypt. Data are shown in Figs 4 and 5 and Table 3.

            FIGURE 4 |

            Prevalence of G genotypes in calves (n=28) in Egypt. G6 was the predominant genotype, followed by G10.

            FIGURE 5 |

            Prevalence of P genotypes in calves (n=28) in Egypt. P[5] was the predominant serotype, followed by P[11].

            TABLE 3 |

            Rotavirus genotypes among Egyptian calves and camels with acute gastroenteritis.

            Area of studyYear of sample collectionNumber of stool samples testedAge (years)Percent positive with rotavirusPredominant G genotypePredominant P genotypeReference
            Alexandria and Ismalia2004–200585Camel calves 2 weeks–4 months old9.50%G10Not typed[86]
            Sharkia and CairoEarly 201525Calves 3 weeks–10 months old48%G6P[11][83]
            Veterinary Teaching Hospital, Faculty of Veterinary Medicine, Assiut UniversityJanuary 2018–November 201916Calves 3–60 days old100%G6P[5][84]

            SEASONAL VARIATION OF ROTAVIRUS IN ANIMALS

            The peak RV infection in animals was detected in the winter [80,84]. RV infections peak during the cold months. This finding may be due to an increased capability to survive at low relative humidity and temperature. Moreover, during the spring and summer the titer of immunoglobulins, such as IgA, IgM, and IgG in colostrum, which provide protection against infections in calves increases while immunoglobulin titers decrease in the autumn and winter [87,88].

            DISTRIBUTION OF ROTAVIRUS STRAINS IN ENVIRONMENTAL SAMPLES

            Many researchers have investigated the prevalence of human RV VP4 and VP7 genotypes in environmental water samples; data are shown in Figs 6 and 7 and Table 4.

            FIGURE 6 |

            Prevalence of G genotypes in sewage samples (n=91) in Egypt. G1 was the most predominant genotype, followed by G3, then G9, G2, and G4.

            FIGURE 7 |

            Prevalence of P genotypes in sewage (n=91) in Egypt. P[8] was the predominant genotype, followed by P[4], then P[6].

            TABLE 4 |

            Rotavirus genotypes in environmental samples.

            Area of studyYear of sample collectionNumber of sewage samplesPercent positive with rotavirusPredominant G genotypePredominant P genotypeReference
            Three sewage treatment plants (Balaks, Zenin, and El Berka) in Cairo, EgyptNovember 1998–October 199935 sewage samples85.70%G1P[8][89]
            Two waste water treatment plants (WWTPs) located at Zenin and El-berka in Greater CairoApril 2006–February 200772 sewage samples8.30%G2P[8][90]
            Zenin wastewater treatment plant (WWTP) in Cairo, EgyptJune 2015–August 2017- 27 raw sewage
            - 27 treated sewage
            - 27 sewage sludge
            - 29.9% raw sewage
            - 7.4% treated sewage
            - 18.5% sewage sludge samples
            G3P[8][91]
            Inlets of El-Gabal El-Asfar and Zenin wastewater treatment plants (WWTPs)October 2015–March 201724 raw sewage samples100%G1P[4][92]
            Wastewater treatment plant (WWTP) in Sharkeya Governorate, EgyptJuly 2016–June 201772 water samples were collected from inlets (n = 36) and outlets (n = 36)- 23.6% raw sewage
            - 16.6% treated wastewater
            G1P[8][93]
            Public café, restaurants and homes found in five separate cities: Cairo, Giza, Helwan, Qalyubia, and FaiyumDecember 2016–November 2017180 tap water samples15.60%G1P[8][94]
            The Nile water stream passing through GizaJune 2016–May 201796 water samples18.75%G1P[8][95]

            Before 2000, G1 was the predominant genotype detected in sewage water [89]. Since that time, two surveillance studies indicated that the G1 genotype was predominant during the 2015–2017 seasons [92,93]. The G2 genotype was the most predominant genotype during the 2006–2007 season [90]; however, another study concluded that the G3 genotype was the predominant genotype [91]. G9 was first detected in sewage samples in 1998 [89], and subsequently detected in other studies [90,91]. G4, G10, and G12 genotypes were also detected in sewage water [8992]. During the 2016–2017 season, RV A was detected in tap water in which G1 constituted >50% of all collected cases, followed by the G2, G4, and G9 genotypes [94]. Another study investigated the presence of RV in Nile water [95], and revealed that G1 was the predominant genotype, followed by G2, then G3 and G9. Several studies have confirmed mixed infections of different RV genotypes in sewage water [89,91] and in the Nile River [95].

            With respect to the VP4 genotypes, P[8] was the predominant genotype detected in sewage water throughout the time period of this review [8991,93]; however, P[4] was the predominant genotype in only one surveillance study [92]. P[6] was also detected in sewage water [89,91,93]. P[8] constituted the predominant genotype of all tap water samples collected [94]. Samples from the Nile River showed that P[8] was the dominant genotype, followed by P[4], then P[6] [95].

            SEASONAL VARIATION OF GROUP A ROTAVIRUS IN ENVIRONMENTAL SAMPLES

            RV in raw sewage was shown to peak during the winter season [91,9395]. The predominance of viral infections during the winter months, which refers to the probable transmission of viral gastroenteritis via a respiratory route, is not completely understood; however, some studies have shown increased virus stability, such as astrovirus, poliovirus, and hepatitis A virus, in the environment at low temperatures [96,97], and therefore higher viral titers in sewage.

            DETECTION OF ROTAVIRUS IN ANIMAL PRODUCTS

            Enteric viruses are major causes of gastroenteritis foodborne outbreaks. Following infection, viruses replicate in the gastrointestinal tract, then shed in human feces. Enteric viruses are transmitted via the fecal–oral route and ingestion of contaminated foods. In the US, viruses are responsible for 35% and 11% of total hospitalizations and death cases associated with foodborne illnesses, respectively [98]. Some researchers in Egypt have investigated the presence of RV in animal products. In a surveillance investigation involving 2400 Egyptian meat and dairy products conducted from January to December 2007, hepatitis A virus and human RV were detected in 5.33% and 6.75%, respectively [99]. In contrast, another study detected bovine RV by ELISA in raw milk and milk products (cheese and yoghurt) during the 2011–2012 season [100].

            INTERSPECIES TRANSMISSION AND ZOONOTIC POSSIBILITY

            RVs have a broad host range, and can infect humans and various animal species. As mentioned before, there are antigenic similarities between human and animal RV strains. Hence, whether or not animals can act as a source of RV infection for humans needs clarification. Another theory suggests that upon certain conditions, animal RVs can definitely infect humans and induce disease. The segmented nature of the genome allows viruses, such as influenza virus and RVs, to form new strains via reassortment. This reassortment can occur during viral replication and packaging as a result of genome segment exchange between two different RV strains infecting the same cell [101]. Theoretically, the 11 genome segments of the parental virus strains can reassort into 2048 [101,102] probable genome constellations if reassortment is random.

            Holmes et al. [55] reported the detection and isolation of the first G8P[14] RV from stool specimens obtained from two Egyptian children. These two strains (EGY1850 and EGY2295), shared a high level of homology of VP7, and with the VP7 sequences from both human and bovine G8 RVs (>82% nucleotide [nt] and >92% amino acid [aa] sequence identity). G8 isolates are commonly detected in cattle, unlike humans. This finding may be caused by the interspecies transmission of RVs between humans and cattle inducing natural reassortants. Sequence analysis of the VP4 genes of both strains revealed 89.6% nt and 97.1% aa sequence identity and greatest homology (>83% nt and >93% aa) to the published P[14] human RV strains. In addition, both strains exhibited 81%–86.9% nt and 91.8%–95.8% aa similarity to the lapine P[14] RV strains. Another report indicated that the G6P[14] genotypic combination was isolated for the first time from a 2-year-old Egyptian child [57], which was the first documented human G6 RV strain in Africa; this strain was designated EGY3399. Sequences of the NSP4 and NSP5 genes of this strain shared the highest similarity of bovine and simian origin, respectively. Moreover, the other genes encoding non-structural proteins were closely related to the genes of animal origin. Interestingly, the three aforementioned atypical Egyptian human P[14] RV isolates are closely related to the bovine G8 and G6 genotypes. A previous study concluded that depending on the VP7 gene sequence, there is a close association of group A RVs between bovine and humans in Egypt [103]. Sequencing of two VP7 isolates (one from a human and one from a calf) showed a high level of VP7 gene homology (95.3% nt and 97.6% aa sequence identity). Thus, this strong identity between the two strains showed that VP7s of bovine RV origin is shared in strains of human RVs. This finding confirms the interspecies transmission of bovine RV to humans, which may be due to the close contact between human and farm animals, especially in developing countries. Another unusual group A RV was detected and isolated for the first time in a stool sample from a child 6 months of age who had acute gastroenteritis in Egypt in 2012 [104]. Full genomic characterization by next-generation sequencing and phylogenetic analysis revealed that the AS997 strain had the consensus P[14] genotype constellation with G9, T1, and H1 reassortment. VP6 was most closely related to human and cat strains with a nt sequence identity of 96.0T and 94.5%, respectively, and clustered with other human strains. The AS997 strain VP2 genotype had a 95.3% nt sequence identity with antelope RVA and clustered with other human and bovine C2 strains.

            Interspecies transmission of RV among animals was also confirmed in Egypt. A study reported RVA infection in dromedary camels in Egypt between 2004 and 2005 [86]. VP7 sequence analysis of the two isolates showed high shared identity to the G10 serotype of group A bovine RVs ranging from 90%–93%. More recently, a study investigated the RVA prevalence among diarrheic children and rats (15.4% and 3.3%, respectively) [105]. Notably, both human and rat sequences shared high identity (99% and 98%, respectively) with human RVA genotype G3P[8] considering that the G3P[8] genotype is the most prevalent human RVA genotype circulating among children in Cairo, Egypt [65].

            CONCLUSIONS AND RECOMMENDATIONS

            RV is the most common causative agent of acute diarrhea in children and animals worldwide. RV is also the main common cause of gastroenteritis in infants, young children, and calves in Egypt. There are currently various commercially-available diagnostic techniques for RV detection in clinical and environmental samples. ELISA and PCR are the most commonly used techniques for detecting, serotyping, and genotyping virus infections. As a result of low human vaccine coverage, the incidence of the RV infection is high in African countries. The same situation exists in animals because there are no commonly administered vaccines for animals in Africa. RV research and genotyping has not been given priority attention in Egypt. This review evaluated the epidemiology of G and P RV genotypes based on data between 1992 and 2022. All the available published studies on RV investigations in Egypt were retrieved from PubMed or other local databases. Variations in the distributions of the G and P genotypes were noted to be linked with temporal and geographic situations. Generally, we found limitations in the depth and quantity of investigations in Egypt. Bovine RV was shown to be a neglected disease in Egypt, although there is high calf mortality because of diarrhea in various regions. There are potent interactions between animal and human group A RV. The zoonotic surveys are limited due to rare availability of genome sequences of animal group A RV. The concurrent investigation of RVA infections in animals, including wild species, and humans, as well as the accumulation of nt sequences from animal strains are critical to recognize the biology, epidemiology, and evolution of such viruses.

            Hence, based on this review, the subsequent points are recommended:

            • Continued human RV surveillance investigations should be performed to recognize new strains circulating in Egypt;

            • A human RV vaccine should be introduced into the National Immunization Program;

            • A human RV vaccine shall include the G9 strain as it is frequently detected;

            • A bovine RV in Egypt should be given more attention from the animal health policy for the implementation of investigations and research reports to enhance the productivity so that the country benefits from the animal health sector;

            • A bovine RV vaccine needs to be introduced into Egypt after detection and characterization of the different strains that cause calf diarrhea; and

            • Future studies, such as a 2-year long surveillance on both environmental and clinical samples with a phylogenetic analysis, are required to elucidate the epidemiology of RV.

            CONFLICTS OF INTEREST

            The authors declare that they have no conflicts of interest with the content of this article.

            REFERENCES

            1. Estes MK, Kapikian AZ. RotavirusesField Virology. Knipe DM, Howley PM, Griffin DE, Lamb RA, Martin MA, Roizman B, et al.. 5th ed. Philadelphia: Lippincott Williams & Wilkins. 2007. p. 1917–1974

            2. Black RE, Cousens S, Johnson HL, Lawn JE, Rudan I, Bassani DG, et al.. Global, regional, and national causes of child mortality in 2008: a systematic analysis. Lancet. 2010. Vol. 375(9730):1969–1987

            3. Lanata CF, Fischer-Walker CL, Olascoaga AC, Torres CX, Aryee MJ, Black RE, et al.. Global causes of diarrheal disease mortality in children <5 years of age: a systematic review. PLoS One. 2013. Sep 4;Vol. 8(9):e72788

            4. Troeger C, Khalil IA, Rao PC, Cao S, Blacker BF, Ahmed T, et al.. Rotavirus vaccination and the global burden of rotavirus diarrhea among children younger than 5 years. JAMA Pediatr. 2018. Vol. 172:958–965

            5. Tate E, Burton AH, Boschi-Pinto C, Parashar UD; World Health Organization–Coordinated Global Rotavirus Surveillance Network. Global, regional, and national estimates of rotavirus mortality in children <5 years of age, 2000–2013. Clin Infect Dis. 2016. Vol. 62:S96–S105

            6. GBD 2016 Causes of Death Collaborators. Global, regional, and national age-sex specific mortality for 264 causes of death, 1980-2016: a systematic analysis for the Global Burden of Disease Study 2016. Lancet. 2017. Sep 16;Vol. 390(10100):1151–1210.

            7. World Health Organization. Summary of key characteristics of currently WHO-Pre-qualified rotavirus vaccines, Version 1.4. https://www.who.int/publications/i/item/WHO-IVB-2021.03Accessed on 15 July 2021

            8. Karami M, Berangi Z. The need for rotavirus vaccine introduction in the national immunization program of more than 100 countries around the world. Infect Control Hosp Epidemiol. 2018. Vol. 39(1):124–125

            9. Dhama K, Chauhan RS, Mahendran M, Malik SV. Rotavirus diarrhea in bovines and other domestic animals. Vet Res Commun. 2009. Jan;Vol. 33(1):1–23

            10. Abe M, Yamasaki A, Ito N, Mizoguchi T, Asano M, Okano T, et al.. Molecular characterization of rotaviruses in a Japanese raccoon dog (Nyctereutes procyonoides) and a masked palm civet (Paguma larvata) in Japan. Vet Microbiol. 2010. Dec 15;Vol. 146(3-4):253–259

            11. Silva LC, Sanches AA, Gregori F, Brandão PE, Alfieri AA, Headley SA, et al.. First description of group A rotavirus from fecal samples of ostriches (Struthio camelus). Res Vet Sci. 2012. Oct;Vol. 93(2):1066–1069

            12. Martella V, Bányai K, Matthijnssens J, Buonavoglia C, Ciarlet M. Zoonotic aspects of rotaviruses. Vet Microbiol. 2010. Jan 27;Vol. 140(3-4):246–255

            13. Pardo-Mora D, Vargas-Bermúdez DS, Oliver-Espinosa O, Jaime-Correa J. Molecular characterization of rotaviruses isolated from calves with bovine neonatal diarrhea (BND) in Colombia. Infectio. 2018. Vol. 22(2):99–104

            14. Kim HJ, Park JG, Matthijnssens J, Lee JH, Bae YC, Alfajaro MM, et al.. Intestinal and extra-intestinal pathogenicity of a bovine reassortant rotavirus in calves and piglets. Vet Microbiol. 2011. Sep 28;Vol. 152(3-4):291–303

            15. Onda K, LoBuglio J, Bartram J. Global access to safe water: accounting for water quality and the resulting impact on MDG progress. Int J Environ Res Public Health. 2012. Mar;Vol. 9(3):880–894

            16. Oude Munnink BB, van der Hoek L. Viruses causing gastroenteritis: the known, the new and those beyond. Viruses. 2016. Feb 8;Vol. 8(2):42

            17. Bosch A, Guix S, Sano D, Pintó RM. New tools for the study and direct surveillance of viral pathogens in water. Curr Opin Biotechnol. 2008. Jun;Vol. 19(3):295–301

            18. Espinosa AC, Mazari-Hiriart M, Espinosa R, Maruri-Avidal L, Méndez E, Arias CF. Infectivity and genome persistence of rotavirus and astrovirus in groundwater and surface water. Water Res. 2008. May;Vol. 42(10-11):2618–2628

            19. Bosch A. Human enteric viruses in the water environment: a minireview. Int Microbiol. 1998. Sep;Vol. 1(3):191–196

            20. Fong TT, Lipp EK. Enteric viruses of humans and animals in aquatic environments: health risks, detection, and potential water quality assessment tools. Microbiol Mol Biol Rev. 2005. Jun;Vol. 69(2):357–371

            21. Sadiq A, Bostan N, Yinda KC, Naseem S, Sattar S. Rotavirus: genetics, pathogenesis and vaccine advances. Rev Med Virol. 2018. Nov;Vol. 28(6):e2003

            22. Bishop RF, Davidson GP, Holmes IH, Ruck BJ. Virus particles in epithelial cells of duodenal mucosa from children with acute non-bacterial gastroenteritis. Lancet. 1973. Dec 8;Vol. 2(7841):1281–1283

            23. Surendran S. Review article: rotavirus infection: molecular changes and pathophysiology. EXCLI J. 2008. Vol. 7:154–162.

            24. Crawford SE, Ramani S, Tate JE, Parashar UD, Svensson L, Hagbom M, et al.. Rotavirus infection. Nat Rev Dis Primers. 2017. Nov 9;Vol. 3:17083

            25. Matthijnssens J, Ciarlet M, McDonald SM, Attoui H, Bányai K, Brister JR, et al.. Uniformity of rotavirus strain nomenclature proposed by the Rotavirus Classification Working Group (RCWG). Arch Virol. 2011. Aug;Vol. 156(8):1397–1413

            26. Mihalov-Kovács E, Gellért Á, Marton S, Farkas SL, Fehér E, Oldal M, et al.. Candidate new rotavirus species in sheltered dogs, Hungary. Emerg Infect Dis. 2015. Apr;Vol. 21(4):660–663

            27. Johne R, Schilling-Loeffler K, Ulrich RG, Tausch SH. Whole genome sequence analysis of a prototype strain of the novel putative rotavirus species L. Viruses. 2022. Feb 24;Vol. 14(3):462

            28. Nagashima S, Kobayashi N, Ishino M, Alam MM, Ahmed MU, Paul SK, et al.. Whole genomic characterization of a human rotavirus strain B219 belonging to a novel group of the genus rotavirus. J Med Virol. 2008. Nov;Vol. 80(11):2023–2033

            29. Molinari BL, Lorenzetti E, Otonel RA, Alfieri AF, Alfieri AA. Species H rotavirus detected in piglets with diarrhea, Brazil, 2012. Emerg Infect Dis. 2014. Jun;Vol. 20(6):1019–1022

            30. Johne R, Otto P, Roth B, Löhren U, Belnap D, Reetz J, et al.. Sequence analysis of the VP6-encoding genome segment of avian group F and G rotaviruses. Virology. 2011. Apr 10;Vol. 412(2):384–391

            31. Bányai K, Kemenesi G, Budinski I, Földes F, Zana B, Marton S, et al.. Candidate new rotavirus species in Schreiber’s bats, Serbia. Infect Genet Evol. 2017. Mar;Vol. 48:19–26

            32. Steger CL, Boudreaux CE, LaConte LE, Pease B, McDonald SM. Group a rotavirus VP1 polymerase and VP2 core shell proteins: intergenotypic sequence variation and in vitro functional compatibility. J Virol. 2019. Vol. 93:e01642-18

            33. World Health Organization (WHO). Rotavirus Vaccines: WHO Position Paper – July 2021. Weekly Epidemiological Record. 2021. Vol. 28:301–320. https://www.who.int/werAccessed on 16 September 2021

            34. RCWG, 2020. Rotavirus classification working group: RCWG – laboratory of viral metagenomics (kuleuven.be). List of Accepted Genotypes. https://rega.kuleuven.be/cev/viralmetagenomics/virus-classification/rcwgAccessed on 13 May 2022

            35. Yen C, Cortese MM. RotavirusesPrinciples and Practice of Pediatric Infectious Diseases. Amsterdam, the Netherlands: Elsevier. 2018. p. 1122–1125.e3

            36. Lequin RM. Enzyme immunoassay (EIA)/enzyme-linked immunosorbent assay (ELISA). Clin Chem. 2005. Dec;Vol. 51(12):2415–2418

            37. Brandt CD, Kim HW, Rodriguez WJ, Thomas L, Yolken RH, Arrobio JO, et al.. Comparison of direct electron microscopy, immune electron microscopy, and rotavirus enzyme-linked immunosorbent assay for detection of gastroenteritis viruses in children. J Clin Microbiol. 1981. May;Vol. 13(5):976–981

            38. El-Ageery MS, Ali R, El-Khier NTA, Rakha SA, Zeid MS. Comparison of enzyme immunoassay, latex agglutination and polyacrylamide gel electrophoresis for diagnosis of rotavirus in children. Egypt J Basic Appl Sci. 2020. Vol. 7(1):47–52

            39. van Zyl WB, Page NA, Grabow WO, Steele AD, Taylor MB. Molecular epidemiology of group A rotaviruses in water sources and selected raw vegetables in Southern Africa. Appl Environ Microbiol. 2006. Jul;Vol. 72(7):4554–4560

            40. Cho Y. Ecology of Calf Diarrhea in Cow-Calf Operations. Dissertations thesis . IOWA State University. Ames, IA, USA: 2012. https://bit.ly/3sRiMyN

            41. Malik YS, Kumar N, Sharma K, Sharma R, Kumar HB, Anupamlal K, et al.. Epidemiology and genetic diversity of rotavirus 144 strains associated with acute gastroenteritis in bovine, porcine, poultry and human population of Madhya Pradesh, Central India, 2004–2008. Adv Anim Vet Sci. 2013. Vol. 1(4):111–115

            42. World Health Organization (WHO). Manual of Rotavirus Detection and Characterization Methods. 2009. World Health Organization. Geneva, Switzerland: https://bit.ly/3ESqNFR

            43. Iturriza Gomara M, Kang G, Mammen A, Jana AK, Abraham M, Desselberger U, et al.. Characterization of G10P[11] rotaviruses causing acute gastroenteritis in neonates and infants in Vellore, India. J Clin Microbiol. 2004. Vol. 42:2541–2547

            44. Matthijnssens J, Otto PH, Ciarlet M, Desselberger U, Van Ranst M, Johne R. VP6-sequence-based cutoff values as a criterion for rotavirus species demarcation. Arch Virol. 2012. Jun;Vol. 157(6):1177–1182

            45. World Health Organization (WHO). Surveillance standards for vaccine-preventable diseases. 2nd edition. https://www.who.int/publications/i/item/surveillance-standards-for-vaccine-preventable-diseases-2nd-editionAccessed on 20 April 2020

            46. Julian TR. Environmental transmission of diarrheal pathogens in low and middle income countries. Environ Sci Process Impacts. 2016. Aug 10;Vol. 18(8):944–955

            47. Li K, Lin XD, Huang KY, Zhang B, Shi M, Guo WP, et al.. Identification of novel and diverse rotaviruses in rodents and insectivores, and evidence of cross-species transmission into humans. Virology. 2016. Vol. 494:168–177

            48. Kilgore PE, Unicomb LE, Gentsch JR, Albert MJ, McElroy CA, Glass RI. Neonatal rotavirus infection in Bangladesh: strain characterization and risk factors for nosocomial infection. Pediatr Infect Dis J. 1996. Aug;Vol. 15(8):672–677

            49. Senecal M, Brisson M, Lebel MH, Yaremko J, Wong R, Gallant LA. Severity, healthcare resource use and work loss related to rotavirus gastroenteritis: a prospective study in community practice. Vol. vol. 3. Vancouver: Canadian Public Health Association. 2006. p. 28–31

            50. Center for Disease Control and Prevention/National Center for Immunization and Respiratory Diseases (CDC/NCIRD). Division of Viral Diseases. https://www.cdc.gov/Accessed on 16 May 2020

            51. Holland RE. Some infectious causes of diarrhea in young farm animals. Clin Microbiol Rev. 1990. Oct;Vol. 3(4):345–375

            52. Perez E, Kummeling A, Janssen MM, Jimenez C, Alvarado R, Caballero M, et al.. Infectious agents associated with diarrhoea of calves in the canton of Tilaran, Costa Rica. Prev Vet Med. 1998. Vol. 33(1-4):195–205

            53. Radwan SF, Gabr MK, El-Maraghi S, El-Saifi AF. Serotyping of group A rotaviruses in Egyptian neonates and infants less than 1 year old with acute diarrhea. J Clin Microbiol. 1997. Nov;Vol. 35(11):2996–2998

            54. Naficy AB, Abu-Elyazeed R, Holmes JL, Rao MR, Savarino SJ, Kim Y, et al.. Epidemiology of rotavirus diarrhea in Egyptian children and implications for disease control. Am J Epidemiol. 1999. Oct 1;Vol. 150(7):770–777

            55. Holmes JL, Kirkwood CD, Gerna G, Clemens JD, Rao MR, Naficy AB, et al.. Characterization of unusual G8 rotavirus strains isolated from Egyptian children. Arch Virol. 1999. Vol. 144(7):1381–1396

            56. Matson DO, Abdel-Messih IA, Schlett CD, Bok K, Wienkopff T, Wierzba TF, et al.. Rotavirus genotypes among hospitalized children in Egypt, 2000-2002. J Infect Dis. 2010. Sep;Vol. 202 Suppl 1:S263–S265

            57. El Sherif M, Esona MD, Wang Y, Gentsch JR, Jiang B, Glass RI, et al.. Detection of the first G6P[14] human rotavirus strain from a child with diarrhea in Egypt. Infect Genet Evol. 2011. Aug;Vol. 11(6):1436–1442

            58. Ahmed SF, Mansour AM, Klena JD, Husain TS, Hassan KA, Mohamed F, et al.. Rotavirus genotypes associated with acute diarrhea in Egyptian infants. Pediatr Infect Dis J. 2014. Jan;Vol. 33 Suppl 1:S62–S68

            59. Afifi NA, EL-Temawy AM, El-Sedafy Gh.O, Hanash SH. Detection of rotavirus infection among children with acute diarrhea in Assiut Pediatric University Hospital: genotying and comparison between strips, EIA and RT-PCR. Egypt J Med Microbiol. 2007. Jan;Vol. 16(1)

            60. Amer MA, Salam SM, Ibrahim HA, Farag MM. Detection of group A rotavirus and characterization of G type among Egyptian children with diarrhea. Egypt J Med Microbiol. 2007. Vol. 16(1):123–132

            61. Kamel AH, Ali MA, El-Nady HG, de Rougemont A, Pothier P, Belliot G. Predominance and circulation of enteric viruses in the region of Greater Cairo, Egypt. J Clin Microbiol. 2009. Apr;Vol. 47(4):1037–1045

            62. Shoeib AR, Abou-Senna AM, ELSayed SE, Zarouk WA, EL-Meleigy MA, El-Esnawy NA. Molecular characterization of rotavirus infection among Egyptian children. New Egypt J Med. 2010. Vol. 42(5):443–450

            63. Sarah H, Shoman SA, Mohamed AF. Isolation and molecular genotyping of group A rotavirus strains circulating among Egyptian infants and children. Egypt J Med Microbiol. 2012. Vol. 21(3):11–20

            64. Saudy N, Elshabrawy WO, Megahed A, Foad MF, Mohamed AF. Genotyping and clinicoepidemiological characterization of rotavirus acute gastroenteritis in Egyptian children. Pol J Microbiol. 2017. Jan 2;Vol. 65(4):433–442

            65. Shoeib AR, Hull JJ, Jiang B. Rotavirus G and P types in children with acute diarrhea in Cairo, Egypt, 2011-2012. J Egypt Public Health Assoc. 2015. Sep;Vol. 90(3):121–124

            66. Shaheen M, Abd EDSE, Hosseney EN, et al.. Molecular characterization of rotavirus strains causing gastroenteritis in children under 5 years in Cairo, Egypt. MOJ Public Health. 2017. Vol. 6(5):428–432

            67. Allayeh AK, El Baz RM, Mohamed Saeed N, El Sayed Osman M. Detection and genotyping of viral gastroenteritis in hospitalized children below five years old in Cairo, Egypt. Arch Pediatr Infect Dis. 2018. Vol. 6(3):e60288

            68. El-Senousy WM, Abu Senna ASM, Mohsen NA, Hasan SF, Sidkey NM. Clinical and environmental surveillance of rotavirus common genotypes showed high prevalence of common P genotypes in Egypt. Food Environ Virol. 2020. Jun;Vol. 12(2):99–117

            69. Magied M, Hussein M, Amer M, Sabah M, Maaty A, Ismaal A, El-Dougdoug K. Investigation of rotavirus genotypes infection in Egypt. Benha J Appl Sci. 2018. Vol. 3(1):107–117

            70. El-Gayar MH, Saleh SE, Mohamed AF, Aboulwafa MM, Hassouna NA, Allayeh AK. Isolation, propagation and genotyping of human rotaviruses circulating among children with gastroenteritis in two Egyptian university hospitals. Biology (Basel). 2022. Sep 28;Vol. 11(10):1413

            71. Fathy M, Amer R, Almalky M, El Gebaly S. Genotyping and severity of rotavirus infection among infants and children with acute diarrhea. Egypt J Hosp Med. 2021. Vol. 82(2):205–211

            72. Clark HF, Hoshino Y, Bell LM, Groff J, Hess G, Bachman P, et al.. Rotavirus isolate WI61 representing a presumptive new human serotype. J Clin Microbiol. 1987. Sep;Vol. 25(9):1757–1762

            73. Than VT, Kang H, Lim I, Kim W. Molecular characterization of serotype G9 rotaviruses circulating in South Korea between 2005 and 2010. J Med Virol. 2013. Jan;Vol. 85(1):171–178

            74. Garaicoechea L, Bok K, Jones LR, Combessies G, Odeon A, Fernandez F, et al.. Molecular characterization of bovine rotavirus circulating in beef and dairy herds in Argentina during a 10-year period (1994-2003). Vet Microbiol. 2006. Vol. 118(1-2):1–11

            75. Shalaby MA, Saber MS, El-Karamany RM. Rotavirus infections associated with diarrhoea in calves in Egypt. Vet Res Commun. 1981. Dec;Vol. 5(2):165–170

            76. Abouel yazeed EA, Yanni MI, Fahmy HA. Virological and molecular studies for detection of bovine rotavirus in neonatal calves in some farms in Egypt. Egypt J Virol. 2014. Vol. 11(1):100–108

            77. Khamees AKS. Detection of Rota and Corona viral antigens in diarrheic newly born calves in Menofiya governorate. Benha Vet Med J. 2015. Vol. 29(1):9–16

            78. Kassem IK, Magouz AF, Desouky AY, Hagag MF. Isolation and identification of rotavirus infection in diarrheic calves at El Gharbia governorate. Glob Vet. 2017. Vol. 18(3):178–182

            79. Saad AA, Abdou NEMI. Molecular diagnosis and matching of rapid and Elisa tests for antigen detection of Rota and Corona viruses in neonatal calves. Anim Health Res Rev. 2017. Jun;Vol. 5(2)

            80. El-Sadek FE, Shahein MA, Abdelwahab SA, El-Shahidy MS. Investigation of Rota and Corona viruses as causative agents for diarrhea in Egyptian calves. Suez Canal Vet Med J. 2019. Vol. 24(2):257–272

            81. Abouelyazeed EA, Hassanien RT, Afify AFM. Cross sectional study for evaluation of rapid test and RT-PCR in detection of BRV in fecal samples of diarrhetic calves in Egypt. Adv Anim Vet Sci. 2021. Vol. 9(3):387–392

            82. Abdel-Rady A, Zaitoun AMA, Youssef ZMA. Clinical study with rapid serological detection of rotavirus infection in diarrheic neonatal calves. Acta Sci Vet Sci. 2022. Vol. 4(2):29–33

            83. Mohamed FF, Mansour SMG, El-Araby IE, Mor SK, Goyal SM. Molecular detection of enteric viruses from diarrheic calves in Egypt. Arch Virol. 2017. Jan;Vol. 162(1):129–137

            84. Zaitoun AMA, Abdel-rady A, Youssef ZMA. Molecular typing of rotaviruses in diarrheic neonatal calves. J Adv Vet Res. 2022. Oct;Vol. 12(5):475–479

            85. Hemida MG. Detection and molecular characterization of group D avian rotavirus in Kafrelsheikh and Gharbia governorates. Alex J Vet Sci. 2013. Vol. 39:145–154

            86. Hatab EA, Hussein HA, El-Sabagh IM, Saber MS. Isolation and antigenic and molecular characterization of G10 of group A rotavirus in camel. Int J Virol. 2009. Vol. 5:18–27

            87. Barua SR, Md Rakib T, Rahman MM, Selleck S, Masuduzzaman M, Siddiki AZ, et al.. Disease burden and associated factors of rotavirus infection in calves in southeastern part of Bangladesh. Asian J Med Biol Res. 2019. Vol. 5(2):107–116

            88. Zaitoun AMA, Abdel-Hakim O, Youssef ZMA. Enteric Rota and Corona viruses’ infection in neonatal calves. Assiut Vet Med J. 2018. Vol. 64(156):8–17

            89. Villena C, El-Senousy WM, Abad FX, Pintó RM, Bosch A. Group A rotavirus in sewage samples from Barcelona and Cairo: emergence of unusual genotypes. Appl Environ Microbiol. 2003. Jul;Vol. 69(7):3919–3923

            90. Kamel AH, Ali MA, El-Nady HG, Aho S, Pothier P, Belliot G. Evidence of the co-circulation of enteric viruses in sewage and in the population of Greater Cairo. J Appl Microbiol. 2010. May;Vol. 108(5):1620–1629

            91. Abd El-Daim SE, Shaheen MNF, Hosseney EN, Elhosainy AM, Nehal IA, Elmahdy ME, et al.. Molecular detection and genotyping of group A rotavirus by multiplex semi-nested RT-PCR in sewage water and sludge. J Microbiol Biotechnol. 2019. Vol. 4(1):000141

            92. El-Senousy WM, Abu Senna ASM, Mohsen NA, Hasan SF, Sidkey NM. Monoplex nested and semi-nested reverse transcription polymerase chain reaction for G and P genotyping of human rotavirus group A in clinical specimens and environmental samples. Int J Curr Res Rev. 2020. Aug;Vol. 12(16):2–8

            93. Rizk N, Al-Herrawy A, Gad M, Shaheen M, Elmahdy E. Existence and removal of rotaviruses group A and Cryptosporidium species in a wastewater treatment plant. Pol J Environ Stud. 2019. Vol. 28(6):4331–4339

            94. Gad MA, Allayeh AK, Elmahdy EM, Shaheen MNF, Rizk NM, Al-Herrawy AZ, et al.. Genotyping and interaction-reality of Acanthamoeba, enteric adenovirus and rotavirus in drinking water, Egypt. Egypt J Aquat Biol Fish. 2019. Vol. 23(2):65–79

            95. Rizk NM, Allayeh AK. Genotyping of rotaviruses in river Nile in Giza, Egypt. Iran J Public Health. 2020. Jan;Vol. 49(1):173–180

            96. Abad FX, Pintó RM, Villena C, Gajardo R, Bosch A. Astrovirus survival in drinking water. Appl Environ Microbiol. 1997. Aug;Vol. 63(8):3119–3122

            97. Nadan S, Walter JE, Grabow WO, Mitchell DK, Taylor MB. Molecular characterization of astroviruses by reverse transcriptase PCR and sequence analysis: comparison of clinical and environmental isolates from South Africa. Appl Environ Microbiol. 2003. Feb;Vol. 69(2):747–753

            98. Scallan E, Hoekstra RM, Angulo FJ, Tauxe RV, Widdowson MA, Roy SL, et al.. Foodborne illness acquired in the United States--major pathogens. Emerg Infect Dis. 2011. Jan;Vol. 17(1):7–15

            99. Zaher KS, Ahmed WM, Syame SM, El-Hewairy HM. Detection of health hazard-food born viruses in animal products anticipated for human consumption. Glob Vet. 2008. Vol. 2(4):192–197

            100. Mohamed HA, Abdou AM, Adel EM, Salem SAH, EL-Hassanine MIM. Detection of rota and corona viruses in raw milk and milk products. Benha Vet Med J. 2013. Vol. 24:79–85

            101. Ramig RF. Genetics of the rotaviruses. Ann Rev Microbiol. 2002. Vol. 51:225–255

            102. Flores J, Sereno M, Lai CJ, Boeggeman E, Perez I, Purcell R, et al.. Use of single-stranded rotavirus RNA transcripts for the diagnosis of rotavirus infection, the study of genetic diversity among rotaviruses, and the molecular cloning of rotavirus genesDouble-stranded RNA Viruses. Compans RW, Bishop DHL. Amsterdam, the Netherlands: Elsevier. 1983

            103. Abdallah F. Close relationship of group A rotaviruses between bovine and human based on VP7 gene sequence in Egypt. Pak Vet J. 2014. Vol. 34(3):391–393

            104. Shoeib A, Velasquez Portocarrero DE, Wang Y, Jiang B. First isolation and whole-genome characterization of a G9P[14] rotavirus strain from a diarrheic child in Egypt. J Gen Virol. 2020. Sep;Vol. 101(9):896–901

            105. Ghoneim NH, Abdel-Moein KA, Saeed H. The zooanthroponotic cycle of human rotavirus in rural settings and its public health burden. Biosci Res. 2019. Vol. 16(1):110–117

            Author and article information

            Contributors
            Journal
            Zoonoses
            Zoonoses
            Zoonoses
            Compuscript (Shannon, Ireland )
            2737-7466
            2737-7474
            11 April 2023
            : 3
            : 1
            : e985
            Affiliations
            [1 ]State Key Laboratory of Agricultural Microbiology, College of Veterinary Medicine, Huazhong Agricultural University, Wuhan, China
            [2 ]Key Laboratory of Preventive Veterinary Medicine in Hubei Province, The Cooperative Innovation Center for Sustainable Pig Production, Wuhan, China
            [3 ]Desert Research Center, Cairo, Egypt
            [4 ]Future Medical Laboratory, Ismailia, Egypt
            [5 ]Faculty of Medicine, Suez Canal University, Ismailia, Egypt
            [6 ]Hubei Hongshan Laboratory, Wuhan, China
            Author notes
            *Corresponding authors: E-mail: he628@ 123456mail.hzau.edu.cn (QH); wentao@ 123456mail.hzau.edu.cn (WL)
            Article
            10.15212/ZOONOSES-2023-0004
            165c6e77-7368-4fb9-b891-8eb470367f3f
            Copyright © 2023 The Authors.

            This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY) 4.0, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

            History
            : 09 January 2023
            : 17 March 2023
            : 25 March 2023
            Page count
            Figures: 7, Tables: 4, References: 105, Pages: 13
            Funding
            Funded by: “Yingzi Tech & Huazhong Agricultural University Intelligent Research Institute of Food Health”
            Award ID: IRIFH202209
            Funded by: China Agriculture Research System of MOF and MARA
            Award ID: CARS-35
            We are grateful to Mrs. Amal EL-Fakharany for data, facilitation, collaboration, and other support during the period of this review. This research was supported by the “Yingzi Tech & Huazhong Agricultural University Intelligent Research Institute of Food Health” (No. IRIFH202209) and China Agriculture Research System of MOF and MARA (No. CARS-35).
            Categories
            Review Article

            Parasitology,Animal science & Zoology,Molecular biology,Public health,Microbiology & Virology,Infectious disease & Microbiology
            Calves,Egypt,Rotavirus A,Rotavirus Genotypes,Human,Zoonoses

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