Genetic evolution of Newcastle Disease Virus sub-genotype VII.2 isolates, diagnosed from vaccinated poultry farms of Gujarat, India.

Newcastle disease was suspected in 37 commercial poultry farms, including 12 layer and 25 broiler farms in four districts of Gujarat, India. Vaccination had been done in 32 (20 broilers and 12 layers) farms. Tissue samples from each farm were pooled as one sample. In egg embryo inoculation, HA-HI and PCR, respectively, 32/37, 29/37, and 24/37 samples were found positive. Pathotyping by mean death time calculation and primer combination PCR revealed velogenic NDV, which was later confirmed with the presence of the 112-RRQKR*F-117 sequence at the F protein cleavage site. Phylogenetic analysis of full F gene sequences (N=10) confirmed the presence of sub-genotype VII.2 in 9/10 sequences, and genotype II in one sample. These 9 sequences were only 0.7 to 2.6 % divergent with two VII.2 (=VIIi) sequences (HQ697254.1 chicken/Banjarmas/Indonesia and KU862293.1 Parakeet/Karachi/Pakistan) but had 2.2 to 3.6 % diversion from two VII.2 sequences (OR185447 and MZ546197) from India. Then branching was found from sequences of VIIh, VIIk (VII.2), and VIIa (VII.1.2), and then from sub-genotypes VII.1.1 and VII.1.2. Due to less than 5 % diversion, these sequences could not be qualified as new sub-genotype in evolutionary distance analysis. At the amino acid level, our sequences had aa N-T-I-A-L-T at 24-79-125-385-445-482. Whereas at the same positions, in most of the retrieved VII.2 sequences and vaccines, the sequence was S-A-V-T-Q/I- E/A. Two sequences revealed additional six and four amino acid differences,respectively.This indicates rapid continuous genetic evolution of sub-genotype VII.2 and partially explains vaccinal immunity escape.

Surveillance and Molecular Characterization of SARS-CoV-2 Infection in Non-Human Hosts in Gujarat, India.

Since December 2019, Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) has been spreading worldwide, triggering one of the most challenging pandemics in the human population. In light of the reporting of this virus in domestic and wild animals from several parts of the world, a systematic surveillance study was conceptualized to detect SARS-CoV-2 among species of veterinary importance. Nasal and/or rectal samples of 413 animals (dogs n= 195, cattle n = 64, horses n = 42, goats n = 41, buffaloes n = 39, sheep n = 19, cats n = 6, camels n = 6, and a monkey n = 1) were collected from different places in the Gujarat state of India. RNA was extracted from the samples and subjected to RT-qPCR-based quantification of the target sequences in viral nucleoprotein (N), spike (S), and ORF1ab genes. A total of 95 (23.79%) animals were found positive, comprised of n = 67 (34.35%) dogs, n= 15 (23.43%) cattle, and n = 13 (33.33%) buffaloes. Whole SARS-CoV-2 genome sequencing was done from one sample (ID-A4N, from a dog), where 32 mutations, including 29 single-nucleotide variations (SNV) and 2 deletions, were detected. Among them, nine mutations were located in the receptor binding domain of the spike (S) protein. The consequent changes in the amino acid sequence revealed T19R, G142D, E156-, F157-, A222V, L452R, T478K, D614G, and P681R mutations in the S protein and D63G, R203M, and D377Y in the N protein. The lineage assigned to this SARS-CoV-2 sequence is B.1.617.2. Thus, the present study highlights the transmission of SARS-CoV-2 infection from human to animals and suggests being watchful for zoonosis.