Changes in thyroid state affect pHi and Nai+ homeostasis in rat ventricular myocytes.

We have tested the hypothesis that thyroid state may influence both the flow of cellular Ca2+ and the myofilament response to Ca2+ by effects on intracellular pH (pHi) and Na+ (Nai+). Single cardiac myocytes isolated from hypothyroid, euthyroid and hyperthyroid animals were loaded with fura-2/AM (Cai2+ probe), BCECF/AM (pHi probe) or SBFI/AM (Nai+ probe). Compared with hypothyroid animals, myocytes isolated from hyperthyroid rat hearts demonstrated a significant: (1) increase in extent of shortening; (2) decrease in the time to peak contraction; (3) increase in the peak amplitude of the fura-2 fluorescence ratio; (4) decrease in pHi (DeltapHi=0. 19+/-0.05); and (5) increase in Nai+ (DeltaNai+=2.88+/-0.55 mM). We have also compared pHi in Langendorff perfused hypo- and hyperthyroid rat hearts using NMR. We have found that hyperthyroid hearts are 0.15+/-0.03 pH units more acidic than hypothyroid hearts. Analysis of mRNA levels demonstrated that hyperthyroidism increased expression of both the Na+/Ca2+ exchanger and Na+/H+ antiporter, and decreased expression of Na+ channel mRNAs. These changes appear partially responsible for the observed changes in Nai+ and pHi. Our results provide the first evidence that changes in cardiac contractility associated with altered thyroid state not only involve effects on Ca2+, but may also involve changes in the response of the myofilaments to Cai2+mediated by altered pHi and Nai+.

Cardiac troponin I mutants. Phosphorylation by protein kinases C and A and regulation of Ca(2+)-stimulated MgATPase of reconstituted actomyosin S-1.

The significance of site-specific phosphorylation of cardiac troponin I (TnI) by protein kinase C and protein kinase A in the regulation of Ca(2+)-stimulated MgATPase of reconstituted actomyosin S-1 was investigated. The TnI mutants used were T144A, S43A/S45A, and S43A/S45A/T144A (in which the identified protein kinase C phosphorylation sites, Thr-144 and Ser-43/ Ser-45, were, respectively, substituted by Ala) and S23A/S24A and N32 (in which the protein kinase A phosphorylation sites Ser-23/Ser-24 were either substituted by Ala or deleted). The mutations caused subtle changes in the kinetics of phosphorylation by protein kinase C, and all mutants were maximally phosphorylated to various extents (1.3-2.7 mol of phosphate/mol of protein). Protein kinase C could cross-phosphorylate protein kinase A sites but the reverse essentially could not occur. Compared to wild-type TnI and T144A, un-phosphorylated S43A/S45A, S43A/S45A/T144, S23A/ S24A, and N32 caused a decreased Ca2+ sensitivity of Ca(2+)-stimulated MgATPase of reconstituted actomyosin. S-1. Phosphorylation by protein kinase C of wild-type and all mutants except S43A/S45A and S43A/S45A/T144A caused marked reductions in both the maximal activity of Ca(2+)-stimulated MgATPase and apparent affinity of myosin S-1 for reconstitued (regulated) actin. It was further noted that protein kinase C acted in an additive manner with protein kinase A by phosphorylating Ser-23/Ser-24 to bring about a decreased Ca2+ sensitivity of the myofilament. It is suggested that Ser-43/Ser-45 and Ser-23/Ser-24 in cardiac TnI are important for normal Ca2+ sensitivity of the myofilament, and that phosphorylation of Ser-43/Ser-45 and Ser-23/Ser-24 is primarily involved in the protein kinase C regulation of the activity and Ca2+ sensitivity, respectively, of actomyosin S-1 MgATPase.

Differential regulation of slow-skeletal and cardiac troponin I mRNA during development and by thyroid hormone in rat heart.

We have examined mRNA levels for the cardiac troponin I (cTnI) and slow-skeletal (ssTnI) in perinatal rat hearts. Northern blots showed that hypothyroidism was associated with a delay in the expected isoform switching. RNA slot blots showed a six-fold increase in cTnI mRNA from day 3 to day 21 in hearts from postnatal euthyroid rats compared to a three-fold increase in cTnI for the same period in the hypothyroid hearts. On the other hand, ssTnI mRNA levels were higher after 3 days in hearts from the hypothyroid animals and fell to undetectable levels after 21 days. In euthyroid hearts ssTnI was not detectable after 14 days and was not re-expressed in adult hearts. In the ventricles from 28-day-old animals the most significant differences in cTnI mRNA levels were between the euthyroid and T3-treated hypothyroid preparations and in the 87 to 125-day-old group between euthyroid and hypothyroid ventricles. T3 treatment of the 87 to 125-day-old hypothyroid animals did not increase the cTnI mRNA above euthyroid levels despite elevated serum T3. These results show that thyroid hormone influences expression of the cTnI isoform in postnatal and young adult rats, but not to the same extent in animals greater than 28 days of age.

Cloning and thyroid hormone regulation of albumin mRNA in Rana catesbeiana tadpole liver.

Thyroid hormones are responsible for the specific biochemical and structural changes that occur during amphibian metamorphosis. In this study we screened a series of cDNAs from a library constructed from T4-treated premetamorphic tadpole liver poly(A)+ RNA in order to identify a clone that could be used to study the influence of T3 on liver-specific gene expression during Rana catesbeiana metamorphosis. The cDNA from one clone exhibited a greater degree of hybridization to liver RNA from thyroid hormone-treated tadpoles than untreated tadpoles and no hybridization to RNA from tail fins of tadpoles of either group. On Northern blots, the mRNA to which the cDNA hybridized was 2.3 kilobases in size. The pattern of hybridization to genomic DNA digested by various restriction enzymes was consistent with the presence of a single gene. Using slot blot analysis we found that the mRNA levels first rose above basal levels only after 5 days of immersion of tadpoles in 12.5 micrograms/liter T3. The mRNA levels increased approximately 10-fold after 7 and 9 days of treatment. Frog livers had mRNA levels that were intermediate between those in untreated tadpoles and tadpoles immersed in T3 for 7 days. Sequence analysis revealed a significant degree of homology to serum albumin and alpha-fetoprotein. While it is known that serum albumin levels rise dramatically during metamorphosis in Rana species, presumably playing a critical role in maintaining water and electrolyte balance during the animals' terrestrial phase, the molecular basis of the induction has not been fully explained.

A hydroxyproline-rich protein in the soybean cell wall.

A cDNA clone that hybridizes to an mRNA (1A10) that accumulates to a substantial level in the axis of the germinating soybean seed was sequenced. The amino acid sequence of the clone indicates an almost perfect repeat of Pro-Pro-Val-Tyr-Lys resulting in a protein containing 40% proline and lacking serine and histidine. On the likelihood that such a protein might be a hydroxyproline-rich cell-wall glycoprotein (HRGP), cell walls of a soybean cell culture were extracted by procedures used to obtain soluble basic cell-wall glycoproteins, and the proteins were fractionated and purified. A 33-kDa protein (and possibly a 28-kDa protein) was obtained that has an amino acid distribution similar to that of the cDNA clone. The protein lacks histidine and serine and contains 20% hydroxyproline and 20% proline. The HRGP is thus distinct both in its amino acid content and in its pentameric repeat of Pro-Pro-Val-Tyr-Lys, with half of the prolines being hydroxylated.

Gene expression in the soybean seed axis during germination and early seedling growth.

Copy-DNA clones have been obtained that distinguish eight messenger mRNAs, moderately abundant in the axes of the germinating soybean (Glycine max (L.) Merr.) seedling. These clones have been used to characterize the size of the mRNAs and to anlyze the accumulation of the mRNAs at different time points and in different parts of the axis during germination and early seedling growth. Three of the mRNAs accumulate to a substantial level by 9 h, a time point before either the beginning of growth or the accumulation of polyribosomes. Four other mRNAs reach a substantial level only at 24 h, a period when rapid seedling growth is occurring. Those mRNAs whose accumulation begins at 24 h were found only in the top (hypocotyl) half of the 24-h seedlings, while the remaining mRNAs were present also in the bottom half of the seedlings in different amounts. By 44 h, the bottom 0.5 cm of the seedlings, i.e., the region of meristematic growth, had little or none of the mRNAs, with the exception of one mRNA. These temporal and spatial observations indicate that many of the mRNAs are not involved simply in the general maintenance of ongoing cell proliferation, but that they may be related to differentiation during early seedling formation. Further, the early accumulating mRNAs may be functioning in regulating the onset of seedling growth.