👤 Michael C Honigberg

Elevated lipoprotein(a) [Lp(a)] levels are an established risk factor for atherosclerotic cardiovascular disease, but the association between Lp(a) and venous thromboembolism (VTE) remains unclear. Sex and hormonal status may modify the relationship between Lp(a) and VTE. The present study included participants from the UK Biobank with available baseline Lp(a) data. Individuals with a history of VTE or cancer, as well as those using anticoagulants, were excluded. Multivariable-adjusted Cox models were used to assess the association between Lp(a) levels ≥ 125 nmol/L and incident VTE in premenopausal women, postmenopausal women, and men. Subgroup analyses stratified premenopausal women by oral contraceptive (OCP) use and postmenopausal women by menopausal hormone therapy (MHT) use. Among 55 302 premenopausal women, 129 045 postmenopausal women, and 189 013 men, the proportions with Lp(a) ≥ 125 nmol/L were 14.0%, 19.0%, and 15.0%, respectively. Over a median (interquartile range) follow-up of 13.6 (12.9-14.4) years, 8186 VTE events occurred (cumulative incidence 2.2%). Lp(a) ≥ 125 nmol/L was associated with incident VTE in premenopausal women [adjusted hazard ratio (aHR) 1.32; 95% confidence interval (CI) 1.04-1.66; P = 0.02] but not in postmenopausal women (aHR 1.03; 95% CI 0.94-1.13; P = 0.47; Pinteraction = 0.03) or men (aHR 1.00; 95% CI 0.92-1.08; P = 0.94). OCP use did not modify the Lp(a)-VTE association among premenopausal women (Pinteraction = 0.61). However, among postmenopausal MHT users, Lp(a) ≥ 125 nmol/L was associated with higher VTE risk (aHR 1.48; 95% CI 1.03-2.12; P = 0.03; Pinteraction = 0.04). Elevated Lp(a) was associated with VTE in premenopausal women and in postmenopausal MHT users, suggesting that hormonal context may influence Lp(a)- associated thrombotic risk. Show less

Circulating lipoprotein(a) [Lp(a)] levels are highly heritable and linked to atherosclerotic cardiovascular disease, yet clinical measurement rates remain low (<1%) in the United States. The high heritability of Lp(a) across populations makes genetic prediction an attractive approach for closing this testing gap, but existing polygenic scores transfer poorly across populations. Haplotype-based prediction models, which use standard genome-wide genotype data to capture common-, rare-, and structural-variation at the LPA locus, could bridge this gap, enabling opportunistic identification of individuals with elevated Lp(a) levels across diverse populations within existing large, genotyped cohorts. This study sought to develop and validate a haplotype-based prediction model using genome-wide genotype data to identify individuals with elevated Lp(a) levels across diverse populations. We developed an Among PMBB (n = 1856), MGBB (n = 1401), and BioMe (n = 1686) participants with available genotype and Lp(a) measurements, average age was 60 years, and 51% were female. Overall r A haplotype-based genetic model effectively identified individuals with elevated Lp(a) levels across diverse populations, with potential utility for opportunistic screening among cohorts where genotype data is available, but Lp(a) testing rates are low. Show less

Elevated lipoprotein(a) [Lp(a)] is an independent risk factor for coronary artery disease (CAD). Data on long-term outcomes following invasive coronary angiography (ICA) in those with elevated Lp(a) are limited. This study examined the association of Lp(a) levels with clinical outcomes after index ICA, accounting for baseline atherosclerotic plaque burden. Data were from participants with Lp(a) measurement who underwent index ICA between 2000 and 2023. Lp(a) levels were categorized as normal (<75 nmol/L), intermediate (75- < 125 nmol/L), high (125- < 175 nmol/L), and very high (≥175 nmol/L). Angiographic characteristics (severity, burden), CAD presentation (stable, acute), and subsequent clinical outcomes [acute myocardial infarction (AMI), revascularization, in-stent restenosis (ISR), and all-cause mortality] were assessed. Among 5118 participants, 973 (19.0%) had very high Lp(a). Compared with normal Lp(a), very high Lp(a) was associated with severe obstructive CAD {adjusted odds ratio (aOR), 1.51 [95% confidence interval (CI), 1.17-1.96]}, left main disease [aOR, 1.67 (95% CI, 1.22-2.29)], and a 14.04-point higher Gensini score (95% CI, 9.57-18.52). During a median (interquartile range) follow-up of 16.87 (6.38-18.99) years, participants with very high vs. normal Lp(a) had higher risk of AMI [adjusted hazard ratio (aHR), 1.20 (95% CI, 1.05-1.37)], revascularization [aHR, 1.32 (95% CI, 1.13-1.56)], ISR [aHR, 1.28 (95% CI, 1.04-1.56)], and mortality [aHR, 1.19 (95% CI, 1.05-1.34)]. Among 798 individuals undergoing coronary artery bypass grafting surgery after index ICA, those with very high vs. other Lp(a) were more likely to require subsequent percutaneous coronary intervention [aHR, 2.20 (95% CI, 1.06-4.58)]. Elevated Lp(a) levels are associated with increased burden of coronary atherosclerosis and significant residual risk for adverse outcomes following ICA, highlighting a need for targeted risk-reduction strategies. Show less

Preeclampsia is a leading cause of maternal and perinatal morbidity and mortality. However, the current understanding of its underlying biological pathways remains limited. In this study, we performed a cross-platform proteome- and transcriptome-wide genetic analysis aimed at evaluating the causal relevance of >2000 circulating proteins with preeclampsia, supported by data on the expression of over 15 000 genes across 36 tissues leveraging large-scale preeclampsia genetic association data from women of European ancestry. We demonstrate genetic associations of 18 circulating proteins with preeclampsia (SULT1A1 [sulfotransferase 1A1], SH2B3 [SH2B adapter protein 3], SERPINE2 [serpin family E member 2], RGS18 [regulator of G-protein signaling 18], PZP [pregnancy zone protein], NOTUM [notum, palmitoleoyl-protein carboxylesterase], METAP1 [methionyl aminopeptidase 1], MANEA [mannosidase endo-alpha], jun-D [JunD proto-oncogene], GDF15 [growth differentiation factor 15], FGL1 [fibrinogen like 1], FGF5 [fibroblast growth factor 5], FES [FES proto-oncogene], APOBR [apolipoprotein B receptor], ANP [natriuretic peptide A], ALDH-E2 [aldehyde dehydrogenase 2 family member], ADAMTS13 [ADAM metallopeptidase with thrombospondin type 1 motif 13], and 3MG [N-methylpurine DNA glycosylase]), among which 11 were either directly or indirectly supported by gene expression data, 9 were supported by Bayesian colocalization analyses, and 5 (SERPINE2, PZP, FGF5, FES, and ANP) were supported by all lines of evidence examined. Protein interaction mapping identified potential shared biological pathways through natriuretic peptide signaling, blood pressure regulation, immune tolerance, and thrombin activity regulation. This investigation identified multiple targetable proteins linked to cardiovascular, inflammatory, and coagulation pathways, with SERPINE2, PZP, FGF5, FES, and ANP identified as pivotal proteins with likely causal roles in the development of preeclampsia. The identification of these potential targets may guide the development of targeted therapies for preeclampsia. Show less

In the yeast Saccharomyces cerevisiae, mitotic cell cycle progression depends upon the G(1)-phase cyclin-dependent kinase Cln-Cdc28 and cell growth to a minimum cell size. In contrast, Cln-Cdc28 inhibits entry into meiosis, and a cell growth requirement for sporulation has not been established. Here, we report that entry into meiosis also depends upon cell growth. Moreover, sporulation and cell growth rates were proportional to cell size; large cells grew rapidly and sporulated sooner while smaller cells grew slowly and sporulated later. In addition, Cln2 protein levels were higher in smaller cells suggesting that Cln-Cdc28 activity represses meiosis in smaller cells by preventing cell growth. In support of this hypothesis, loss of Clns, or the presence of a cdc28 mutation increased cell growth specifically in smaller cells and accelerated meiosis in these cells. Finally, overexpression of CLNs repressed meiosis in smaller cells, but not in large cells. Taken together, these results demonstrate that Cln-Cdc28 represses entry into meiosis in part by inhibiting cell growth. Show less

As yeast colonies ceased growth, cells at the edge of these colonies transited from the cell division cycle into meiosis at high efficiency. This transition occurred remarkably synchronously and only at late stages of colony maturation. The transition occurred on medium containing acetate or low concentrations of glucose, but not on medium containing high glucose. The repression by high glucose was overcome when IME1 was overexpressed from a plasmid. Experiments with different growth media imply that meiosis in colonies is triggered by changes in the nutrient environment as colonies mature. HAP2 is required to sporulate in any carbon source, whereas GRR1 is required for glucose repression of sporulation. CLN3 is required to repress meiosis in colonies but not in liquid cultures, indicating that the regulators that mediate the transition to meiosis in colonies are not identical to the regulators that mediate this transition in liquid cultures. Show less

IME1, which is required for the initiation of meiosis, is regulated by Cln3:Cdc28 kinase, which activates the G1-to-S transition, and Snf1 kinase, which mediates glucose repression. Here we examine the pathway by which Cln3:Cdc28p represses IME1 and the relationship between Cln3:Cdc28p and Snf1p in this regulation. When wild-type yeast cease growth, they express IME1 to moderate levels, intermediate between the low levels expressed during growth and the high levels expressed during sporulation. Moderate IME1 expression occurred in cln3Delta, cln1Delta cln2Delta, cdc28-4 and swi6Delta mutants, even during growth. These mutants also induced IME1 expression more rapidly than the wild-type. CLN3 required SWI6 and CLN2 to repress IME1 and IME2, but CLN1 was much less active than CLN2 in this repression. The phenotype of the cln3Delta snf1Delta double mutant indicated that Cln3:Cdc28p regulates IME1 independently of SNF1. Entry into meiosis involves two independent but sequential controls, which regulate IME1 via a three position switch: (i) during growth IME1 is repressed by the CLN3/SWI6/CLN2 pathway, (ii) once growth ceases, this repression is released and IME1 is expressed at moderate levels, and (iii) subsequently, nutritional conditions that activate Snf1p allow high IME1 expression. Show less