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Vol. 51 No. 3, 2012
Identification of the Crustacean Hyperglycemic Hormone (CHH) and CHH-like Peptides in the Crayfish Procambarus clarkii and Localization of Functionally Important Regions of the CHH
Hsin-Ju Wu, Wei-Shiun Tsai, Shao-Yen Huang, Yan-Jhou Chen, Ying-Hsin Chen, Yu-Ru Hsieh, and Chi-Ying Lee*
Department of Biology, National Changhua University of Education, Changhua 500, Taiwan
Hsin-Ju Wu, Wei-Shiun Tsai, Shao-Yen Huang, Yan-Jhou Chen, Ying-Hsin Chen, Yu-Ru Hsieh, and Chi-Ying Lee (2012) Four
anti-peptide antibodies were raised each against a synthetic peptide
corresponding in sequence to a short stretch of the crustacean
hyperglycemic hormone (CHH) or CHH-like (CHH-L) peptides of the
crayfish Procambarus clarkii.
CHH and CHH-L are alternatively spliced products that share an
identical sequence for the 1st 40 residues from the amino-terminus of
the peptides. When used in Western blot analyses of tissue proteins,
anti-CHH (1-10) recognized an immunoreactive protein band in both sinus
gland (SGs) and thoracic ganglia (TGs), whereas anti-D-CHH (1-10)
recognized an immunoreactive protein band only in SGs, but not in TGs;
anti-CHH (59-72) recognized an immunoreactive protein band in SGs but
not in TGs, and conversely, anti-CHH-L (58-72) recognized an
immunoreactive protein band in TGs but not in SGs. Tissue homogenates
were fractionated using high-performance liquid chromatography (HPLC).
The immunoreactivity of the collected HPLC fractions was determined by
an enzyme-linked immunosorbent assay and Western blotting, and the
immunoreactive fractions were subjected to mass determination. A pair
of stereoisomers, CHH and D-Phe3 CHH, both with a mass of 8386.4 and
respectively immunoreactive to anti-CHH (1-10) and anti-DCHH (1-10),
was identified in SGs; Western blot analyses showed that they were
immunoreactive to anti-CHH (59-72), but not to anti-CHH-L (58-72). A
CHH-L, with a mass of 8343.6 and immunoreactive to anti-CHH (1-10) but
not to anti-D-CHH (1-10), was identified in TGs; Western blot analyses
showed that it was immunoreactive to anti-CHH-L (58-72), but not to
anti-CHH (59-72), and sequencing analysis of the peptide fragments
generated by enzyme digestion of the immunoreactive protein revealed 3
sequences, which are contained within a CHH-L encoded by a previously
identified transcript. Furthermore, anti-peptide antibodies were tested
for the effects of blocking CHH-induced hyperglycemia. Results showed
that anti-CHH (59-72) and anti-CHH (1-10) individually abolished
CHH-induced hyperglycemia, whereas neither control treatments,
pre-immune sera, nor anti-CHH-L (58-72) significantly affected
CHH-induced hyperglycemia. In summary, these data reiterate the
observations that CHH and CHH-L are preferentially expressed in
different tissues; they also suggest that enzymes involved in L-to-D
isomerization of CHH are expressed in tissue-specific manners. Finally,
the data suggest the N- and C-terminal regions of CHH are important for
its biological activity.
Key words: Neuroendocrine, Neuropeptide, Anti-peptide antibody, Crustacean.
*Correspondence: Tel: 886-4-7247756. Fax: 886-4-7211156. E-mail:bicylee@cc.ncue.edu.tw
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