The initial trigger for sexual differentiation is regulated by multiple ways during embryonic development. In vertebrates, chromosome-based mechanisms generally known as genetic sex determination are prevalent; however, some species, such as many reptilians, display temperature-dependent sex determination. The Sry-related transcription factor, Sox9, which is expressed by an evolutionary conserved gene, has been shown to be a key player in the process of sex determination. In the present study, we report the identification and expression of crocodile homolog of Sox9 (cpSox9) from the Indian Mugger, Crocodylus palustris. We show that cpSox9 undergoes extensive alternative splicing around the proline-glutamine-alanine rich transactivation domain that results in cpSox9 variants with presumably impaired or reduced transactivation potential. The multiple isoforms were also detected in various embryonic tissues, with some of them displaying a differential expression profile. With respect to sex differentiation, a putative unspliced full-length cpSox9 could be detected only in the genital ridge-adrenal-mesonephros complex of male, but not female embryos during the temperature-sensitive period. Importantly, we further show that this phenomenon was not restricted to the temperature-dependent sex determination species C. palustris, but was also observed in the mouse, a species exhibiting genetic sex determination. Thus, the present study describes, for the first time, a complete coding locus of Sox9 homolog from a temperature-dependent sex determination species. More importantly, we demonstrate an evolutionarily conserved role of alternative splicing resulting in transcriptional diversity and male-sex specific expression of Sox9 during testis development in vertebrates (i.e. irrespective of their underlying sex-determination mechanisms).