溶源性巨大芽孢杆菌适应硫酸铵培养基后新噬菌体类型和新溶源菌株的出现。
Appearance of new phage types and new lysogenic strains after adaptation of lysogenic B. megatherium to ammonium sulfate culture medium.
作者信息
NORTHROP J H, MURPHY J S
出版信息
J Gen Physiol. 1956 Mar 20;39(4):607-24. doi: 10.1085/jgp.39.4.607.
Abstract
- Lysogenic B. megatherium 899a was adapted to growth in a minimal ammonium sulfate medium (ASCM). 2. Adaptation took place slowly and the following changes in the culture occurred: (a) The growth rate increased from 0.5 to 1.5-2.0/hr. (b) The culture changed from diffuse to mucoid. (c) The total phage titer, and the gelatinase concentration decreased to 1/100 or less. (d) The types of phage produced changed from >99 per cent T (wild type) to 30 to 60 per cent miscellaneous clear types. The original T phage was replaced by a different smaller t, never observed in the original 899a culture. (e) Several new colony types also appeared, but the colony morphology was not correlated with the phage types produced. None of the colony types was stable on repeated transfer either in peptone or ASCM, but continued to disassociate into different colony types (cf. Ivánovics, 1955). 3. Control experiments showed that these changes in phage production and colony types could not be brought about by growing sensitive B. megatherium in the presence of the various new phages, in ASCM. It is therefore unlikely that the changes observed in adapted culture were due to infection of a sensitive cell with phage. 4. Continued growth of the ASCM-adapted strain in peptone resulted in increasing the total phage titer, and also the gelatinase concentration. The growth rate returned to its original value and the ability to grow rapidly in ASCM was soon lost. The phage types, however, remained the same as in the ASCM. 5. An improved cell for steady state growth is described.
摘要
- 溶源性巨大芽孢杆菌899a适应在最低限度的硫酸铵培养基(ASCM)中生长。2. 适应过程缓慢,培养物发生了以下变化:(a)生长速率从0.5提高到1.5 - 2.0/小时。(b)培养物从扩散型变为黏液型。(c)噬菌体总滴度和明胶酶浓度降至1/100或更低。(d)产生的噬菌体类型从>99%的T型(野生型)变为30%至60%的各种透明型。原来的T噬菌体被一种不同的较小的t噬菌体取代,在原始的899a培养物中从未观察到。(e)还出现了几种新的菌落类型,但菌落形态与产生的噬菌体类型无关。在蛋白胨或ASCM中反复传代时,没有一种菌落类型是稳定的,而是继续分解为不同的菌落类型(参见伊万诺维奇,1955年)。3. 对照实验表明,在ASCM中,在各种新噬菌体存在的情况下培养敏感的巨大芽孢杆菌,不会导致噬菌体产生和菌落类型的这些变化。因此,适应培养物中观察到的变化不太可能是由于敏感细胞被噬菌体感染所致。4. 在蛋白胨中继续培养适应ASCM的菌株,会导致噬菌体总滴度以及明胶酶浓度增加。生长速率恢复到其原始值,并且在ASCM中快速生长的能力很快丧失。然而,噬菌体类型与在ASCM中时保持相同。5. 描述了一种用于稳态生长的改良细胞。
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