Chad M. Warren

Titin isoform expression in normal and hypertensive myocardium

OBJECTIVE Titin isoform expression patterns were examined to explain previously observed genetic differences in rat cardiac passive tension. METHODS Rat ventricles from male spontaneously hypertensive (SHR) and Wistar-Kyoto (WKY) rats (normotensive) were used to analyze the titin isoform patterns. The hypertensive status was verified by blood pressure measurements and heart weight to body weight ratios. Gel electrophoresis and scanning densitometry were performed to determine ratios of myosin heavy chain and titin isoforms expressed. In situ hybridization using a cRNA probe specific for N2BA titin and a positive control in the N2B unique region was used to demonstrate tissue location of the titin message. RESULTS Regression analysis of titin isoform ratios, myosin heavy chain isoform ratios, and heart weight to body weight ratios all suggest a smaller proportion of N2BA titin (longer isoform) was expressed in rat left ventricles with increased hypertrophy. In situ hybridization showed that the N2BA and N2B isoforms were co-expressed within most of the cardiomyocytes. Agarose gel electrophoresis demonstrated two different N2BA titin isoforms in all rat ventricles. CONCLUSIONS Expression of less N2BA and more N2B titin in response to pressure overload will result in higher passive tension upon stretch at a given sarcomere length and thus affect cardiac performance.

Titin isoform changes in rat myocardium during development

Developmental changes in the alternative splicing patterns of titin were observed in rat cardiac muscle. Titin from 16-day fetal hearts consisted of a single 3710 kDa band on SDS agarose gels, and it disappeared by 10 days after birth. The major adult N2B isoform (2990 kDa) first appeared in 18-day fetal hearts and its proportion in the ventricle increased to approximately 85% from 20 days of age and older. Changes in three other intermediate-sized N2BA isoform bands also occurred during this same time period. The cDNA sequences of fetal cardiac, adult ventricle, and adult soleus were different in the PEVK and alternatively spliced middle Ig domain. Extensive heterogeneity in splice patterns was found in the N2BA PEVK region. The extra length of the fetal titin isoforms appeared to be due to both a greater number of middle Ig domains expressed plus the inclusion of more PEVK exons. Passive tension measurements on myocyte-sized fragments indicated a significantly lower tension in neonate versus adult ventricles at sarcomere lengths greater than 2.1 microm, consistent with the protein and cDNA sequence results. The time course of the titin isoform switching was similar to that occurring with myosin and troponin I during development.

Mutation that dramatically alters rat titin isoform expression and cardiomyocyte passive tension

Titin is a very large alternatively spliced protein that performs multiple functions in heart and skeletal muscles. A rat strain is described with an autosomal dominant mutation that alters the isoform expression of titin. While wild type animals go through a developmental program where the 3.0 MDa N2B becomes the major isoform expressed by two to three weeks after birth (approximately 85%), the appearance of the N2B is markedly delayed in heterozygotes and never reaches more than 50% of the titin in the adult. Homozygote mutants express a giant titin of the N2BA isoform type (3.9 MDa) that persists as the primary titin species through ages of more than one and a half years. The mutation does not affect the isoform switching of troponin T, a protein that is also alternatively spliced with developmental changes. The basis for the apparently greater size of the giant titin in homozygous mutants was not determined, but the additional length was not due to inclusion of sequence from larger numbers of PEVK exons or the Novex III exon. Passive tension measurements using isolated cardiomyocytes from homozygous mutants showed that cells could be stretched to sarcomere lengths greater than 4 mum without breakage. This novel rat model should be useful for exploring the potential role of titin in the Frank-Starling relationship and mechano-sensing/signaling mechanisms.

Species variations in cDNA sequence and exon splicing patterns in the extensible I-band region of cardiac titin: relation to passive tension

473 Titin is believed to playa major role in passive tension development in cardiac muscle . The eDNA sequence of cardiac titin in the I-band sarcomeric region was determined for several mammalian species. Contiguous sequences of 3749, 12,230, 6602, and 11,850 base pairs have been obtained for the rat N2B, rat N2BA, dog N2B, and dog N2BA isoforms respectively. The length of the PEVK region of the N2B isoform did not correlate with rest tension properties since the only species showing an altered length was the dog that expressed a shorter form . No differences were found between the N2B PEVK lengths in ventricular and atrial muscle. New N2BA splicing pathways in the first tandem Ig region were found in human and dog cardiac muscle . Most of the rat and dog sequences were 8595% identical with the reported human sequence. However, the N2B unique amino acid sequences of rat and dog were only 51 and 67% identical to human. The rat N2B unique sequence was 526 amino acids in length compared to 572 in human. The difference in length was due to deletion of amino acid segments from six different regions of the N2B unique domain. Patterns of PEVK exon expression were also much different in the dog, human, and rat. Six separate dog N2BA PEVK clones were sequenced, and all had different exon splice combinations yielding PEVK lengths ranging from 703 to 900 amino acids. In contrast a rat N2BA clone had a PEVK length of 525 amino acids , while a human clone had an 908 amino acid PEVK segment. Thus, in addition to the higher proportion of the shorter N2B isoform found in rat compared with dog cardiac muscle observed previously, shorter N2B unique and N2BA PEVK segments may also contribute to the greater passive tension in cardiac muscle from rats .

Efficient Electroblotting of Very Large Proteins Using a Vertical Agarose Electrophoresis System

Very large proteins (subunit sizes >200 kDa) are difficult to electrophoretically separate, and they are also challenging to analyze by western blotting because of their incomplete transfer out of polyacrylamide gels. An SDS vertical agarose gel system has been developed that has vastly improved resolving power for very large proteins. The large pores of the agarose also allow full transfer of proteins as large as titin (Mr =3,000-3,700 kDa) onto blots. Inclusion of a reducing agent in the upper reservoir buffer and transfer buffer has been found to be a key technical procedure in blotting large proteins.