Abstract
The growth of the rat lung was studied at six ages, from 18 days of fetal life to old age (i.e. 105 weeks). Most of the increase in lung size appeared to involve cellular hyperplasia rather than hypertrophy, the DNA content of the lung increasing 96-fold from one extreme of life to the other. Pulmonary rates of protein turnover were high and were, age for age, consistently greater than the rates in the whole body. The age-related decline in the rate of lung growth corresponded to a marked decrease in the fractional rate of protein synthesis, i.e. from 93 to 33% per day during fetal and neonatal life. This in turn correlated with a 58% fall in the ribosomal capacity. From weaning onwards, synthesis rates remained between 30 and 40% per day. In contrast, the degradation of lung proteins was unchanged, at 28-38% per day throughout both fetal and post-natal life.
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Selected References
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