ABSTRACT
Heart failure is caused by various factors, making the underlying pathogenic mechanisms difficult to identify. Since cardiovascular disease tends to worsen over time, early diagnosis is key for treatment. In addition, understanding the qualitative changes in the heart associated with aging, where information on the direct influences of aging on cardiovascular disease is limited, would also be useful for treatment and diagnosis. To fill these research gaps, the focus of our study was to detect the structural and functional molecular changes associated with the heart over time, with a focus on glycans, which reflect the type and state of cells. METHODS: We investigated glycan localization in the cardiac tissue of normal mice and their alterations during aging, using evanescent-field fluorescence-assisted lectin microarray, a technique based on lectin-glycan interaction, and lectin staining. RESULTS: The glycan profiles in the left ventricle showed differences between the luminal side (medial) and wall side (lateral) regions. The medial region was characterized by the presence of sialic acid residues. Moreover, age-related changes in glycan profiles were observed at a younger age in the medial region. The difference in the age-related decrease in the level of α-galactose stained with Griffonia simplicifolia lectin-IB4 in different regions of the left ventricle suggests spatiotemporal changes in the number of microvessels. CONCLUSIONS: The glycan profile, which retains diverse glycan structures, is supported by many cell populations, and maintains cardiac function. With further research, glycan localization and changes have the potential to be developed as a marker of the signs of heart failure.
ABSTRACT
Mammalian X and Y chromosomes evolved from a pair of autosomes. Although most ancestral genes have been lost from the Y chromosome, a small number of ancestral X-Y gene pairs are still present on the sex chromosomes. The KDM5C and KDM5D genes, which encode H3K4 histone demethylases, are a surviving ancestral gene pair located on the X and Y chromosomes, respectively. Mutations in KDM5C cause X-linked intellectual disability in human males, suggesting functional divergence between KDM5C and KDM5D in the nervous system. In this study, to explore the functional conservation and divergence between these two genes in other organs, we generated female mice lacking Kdm5c (homozygous X5c- X5c- females) and male mice lacking both Kdm5c and Kdm5d (compound hemizygous X5c- Y5d- males). Both X5c- X5c- females and X5c- Y5d- males showed lower body weights and postnatal lethality. Histological examination of the hearts showed prominent trabecular extension and a thin layer of compacted myocardium in the left and right ventricles, indicating noncompaction cardiomyopathy. However, hemizygous males lacking either Kdm5c or Kdm5d showed no signs of noncompaction cardiomyopathy. These results clearly demonstrate that the function of Kdm5c and Kdm5d in heart development is conserved.
