Genetic variation of the transthyretin gene in wild-type transthyretin amyloidosis (ATTRwt).

Wild-type transthyretin amyloidosis (ATTRwt), typically diagnosed as congestive heart failure in elderly Caucasian men, features myocardial amyloid deposits of wild-type plasma protein transthyretin (TTR). ATTRwt is sporadic, its pathogenesis is poorly understood, and currently there are no biomarkers for diagnosis or prognosis. Genetic studies of variant-associated transthyretin amyloidosis have suggested that non-coding TTR gene variants modulate disease. We hypothesized that cis-acting regulatory elements in the TTR gene non-coding regions may modify expression, affecting ATTRwt onset and progression. We studied an ATTRwt cohort consisting of 108 Caucasian males ranging in age from 59 to 87 years with cardiomyopathy due to wild-type TTR deposition; results were compared to 118 anonymous controls matched by age, sex, and race. Four predicted non-coding regulatory regions and all exons in the TTR gene were sequenced using the Sanger method. Eleven common variants were identified; three variants were significantly associated with ATTRwt (p < 0.05), though only one, rs72922940, remained near significance (p corrected = 0.083) after multiple testing correction. Exon analyses demonstrated the occurrence of the p.G26S (G6S) polymorphism in 7 % of ATTRwt subjects and 12 % of controls; this variant was predicted to be a protective factor (p = 0.051). Four variants were significantly associated with age at onset and survival. In this first genetic study of a large, well-characterized cohort of ATTRwt, non-coding and coding variants associated with disease, age at onset, and survival were identified. Further investigation is warranted to determine the prevalence of these variants in ATTRwt, their regulatory function, and potential role in assessing disease risk.

Dimer exchange and cleavage specificity of the DNA damage response protein UmuD.

The cellular response to DNA damage in Escherichia coli is controlled in part by the activity of the umuD gene products. The full-length dimeric UmuD(2) is the initial product that is expressed shortly after the induction of the SOS response and inhibits bacterial mutagenesis, allowing for error-free repair to occur. Over time, the slow auto-cleavage of UmuD(2) to UmuD'(2) promotes mutagenesis to ensure cell survival. The intracellular levels of UmuD(2) and UmuD'(2) are further regulated by degradation in vivo, returning the cell to a non-mutagenic state. To further understand the dynamic regulatory roles of the umuD gene products, we monitored the kinetics of exchange and cleavage of the UmuD(2) and UmuD'(2) homodimers as well as of the UmuDD' heterodimer under equilibrium conditions. We found that the heterodimer is the preferred but not exclusive protein form, and that both the heterodimer and homodimers exhibit slow exchange kinetics which is further inhibited in the presence of interacting partner DinB. In addition, the heterodimer efficiently cleaves to form UmuD'(2). Together, this work reveals an intricate UmuD lifecycle that involves dimer exchange and cleavage in the regulation of the DNA damage response.

The dimeric SOS mutagenesis protein UmuD is active as a monomer.

The homodimeric umuD gene products play key roles in regulating the cellular response to DNA damage in Escherichia coli. UmuD(2) is composed of 139-amino acid subunits and is up-regulated as part of the SOS response. Subsequently, damage-induced RecA·ssDNA nucleoprotein filaments mediate the slow self-cleavage of the N-terminal 24-amino acid arms yielding UmuD'(2). UmuD(2) and UmuD'(2) make a number of distinct protein-protein contacts that both prevent and facilitate mutagenic translesion synthesis. Wild-type UmuD(2) and UmuD'(2) form exceptionally tight dimers in solution; however, we show that the single amino acid change N41D generates stable, active UmuD and UmuD' monomers that functionally mimic the dimeric wild-type proteins. The UmuD N41D monomer is proficient for cleavage and interacts physically with DNA polymerase IV (DinB) and the ß clamp. Furthermore, the N41D variants facilitate UV-induced mutagenesis and promote overall cell viability. Taken together, these observations show that a monomeric form of UmuD retains substantial function in vivo and in vitro.