Post-secretory aggregation of caseins

Brooker, B. E.; Holt, Carl

doi:10.1017/s0022029900017039

Cited by 8 publications

(4 citation statements)

References 10 publications

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“…It is not possible to say if these 2 micellar aspects correspond to different native micelles or are instead induced by the sampie preparation. In any case, they demonstrate the existence in the micelles of a filamentous structure for the caseins, analogous to that already seen in the Golgi vesicles (Brooker and Holt, 1979). The internai parts of the micelles look homogeneous with a continuous electron-dense structure.…”

Section: Répartition Du Nombre Des Micelles Et Du Volume Selon La Taisupporting

confidence: 73%

Variation in size of goat milk casein micelles related to casein genotype

Aimar

Michel

Graët

1995

Lait

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Summary -Casein (CN) micelle size was determined in 2 goat milks from animais with different genotype for OEs1CN.One milk lacked OEs1CN,the other had an OEs1CNcontent of 4.7 9 kg-l, ln comparison, the goat bulk milk has 3.3 9 kg-1 OEs1CN.The mean diameter of micelles in milk without OEs1CNwas found to be 280 nm, while the diameter was 199 nm in milk with a high content of OEs1CN, ie a decrease by 29%. Micellar sizes were estimated by photon correlation spectroscopy (PCS) and by transmission electron microscopy (TEM) associated with negative staining. Miceilar volume distribution according to slze showed that milk without OE s lCN had the typical distribution of goat milk, ie a large spread of diameters from 20 to 270 nm without any clear maximum in frequency and a high proportion of case in forming the large micelles. In contrast, milk with a high level of OEs1CNshowed a narrow unimodal distribution of frequency. The chemical analysis of milks, total casein, individual caseins, total and soluble minerais showed that the only difference is the OEs1CN level. The results might imply a role of OEslCN in miceile size regulation.goat milk 1 casein 1 micelle 1 OEslcasein 1 size 1 TEM microscopy 1 photon correlation spectroscopy Résumé -Taille des micelles de caséine du lait de chèvre en relation avec la variation géné-tique de la composition du lait.

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Section: Répartition Du Nombre Des Micelles Et Du Volume Selon La Taisupporting

confidence: 73%

Variation in size of goat milk casein micelles related to casein genotype

Aimar

Michel

Graët

1995

Lait

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“…However, we cannot conclude whether the structural organization of the calcium-sensitive caseins in the micelle-like particles is similar to that of the wild-type micelles. It has been suggested that the organization of micelles continues even after their secretion into the lumina (27). It is very likely that the absence of -casein severely interrupts this process of micelle reorganization in the alveolar lumen and leads to destabilization of the secreted particles, culminating in aggregation of the calcium-sensitive caseins in the alveolar lumina.…”

Section: Discussionmentioning

confidence: 99%

κ-Casein-deficient mice fail to lactate

Shekar

Goel

Rani

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

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Acquisition of milk production capabilities by an ancestor of mammals is at the root of mammalian evolution. Milk casein micelles are a primary source of amino acids and calcium phosphate to neonates. To understand the role of -casein in lactation, we have created and characterized a null mouse strain (Csnk ؊/؊ ) lacking this gene. The mutant -casein allele did not affect the expression of other milk proteins in Csnk ؊/؊ females. However, these females did not suckle their pups and failed to lactate because of destabilization of the micelles in the lumina of the mammary gland. Thus, -casein is essential for lactation and, consequently, for the successful completion of the process of reproduction in mammals. In view of the extreme structural conservation of the casein locus, as well as the phenotype of Csnk ؊/؊ females, we propose that the organization of a functional -casein gene would have been one of the critical events in the evolution of mammals. Further, -casein variants are known to affect the industrial properties of milk in dairy animals. Given the expenses and the time scale of such experiments in livestock species, it is desirable to model the intended genetic modifications in mice first. The mouse strain that we have created would be a useful model to study the effect of -casein variants on the properties of milk and͞or milk products.casein locus ͉ evolution ͉ lactation ͉ milk ͉ micelle M ilk production is an essential component of the reproductive strategy of mammals. The development of a zygote into an organism is accompanied by the preparation of milk synthesis potential by the mammary gland. Perinatal survival in mammals is solely dependent on the availability of milk from the mother. Caseins account for Ͼ80% of the total milk proteins (1). These proteins exist as micelles, consisting of three to four phosphoproteins (i.e., the calcium-sensitive caseins: ␣-, ␤-, ␥-, and ␦-casein in mice) and a calcium-insensitive phosphoglycoprotein, -casein (2). In addition to functioning as the primary source of amino acids, one of the key functions of micelles is to sequester large amounts of calcium phosphate from the maternal diet or bodily stores and make it readily available to the newborn. Calcium-sensitive casein genes seem to have evolved from a primitive casein gene through gene duplication and exon shuffling (3); however, it appears that -casein is not related structurally and evolutionarily to these genes. Instead, it appears to be related to ␥-fibrinogen (4, 5). Recently, it has also been speculated that both the calcium-sensitive and the calciuminsensitive casein gene belong to one gene family (6). The null mutation of the ␤-casein gene in mice (7) and that of ␣ S1 -casein in goats (8) do not show any significant effect on milk micelle formation and lactation. The lack of adverse effects on micelle formation in these mutants suggests functional redundancy amongst calcium-sensitive caseins. However, the absence of ␣ S1 -casein in goats does affect the rate of transport of caseins. The experimental ev...

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“…These data indicated slow secretion of larger micelles or a stepwise growth of the casein micelles as suggested by Schmidt (1980). The presence of more than one peak of 45 Ca and 32 P in large-sized casein micelles may be due to post-secretory growth of the micelles in the alveolar lumen (Brooker & Holt, 1979).…”

Section: Discussionmentioning

confidence: 99%

Incorporation of³²P and⁴⁵Ca into milk and casein micelles of a buffalo (Bubalus bubalis) following intramuscular injection

Bhushan

Singh

Ahuja

1983

Journal of Dairy Research

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During lactation, large quantities of Ca and P are absorbed from the blood and are secreted into milk by the mammary secretory cells. Apart from some preliminary reports (Abd-Elwahab & Raafat, 1961; Raafat & Abd-Elwahab, 1961; Ahuja & Jassal, 1979, Bhushan et al. 1982), little work appears to have been done on their secretion into buffalo milk, especially in association with milk proteins which determine the quality of milk products such as cheese during their manufacture. The present study was, therefore, carried out to study the rate of secretion of 32 P and 45 Ca from blood into milk and their incorporation into the casein micelles of buffalo milk.

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Post-secretory aggregation of caseins

Cited by 8 publications

References 10 publications

Variation in size of goat milk casein micelles related to casein genotype

Variation in size of goat milk casein micelles related to casein genotype

κ-Casein-deficient mice fail to lactate

Incorporation of³²P and⁴⁵Ca into milk and casein micelles of a buffalo (Bubalus bubalis) following intramuscular injection

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Post-secretory aggregation of caseins

Cited by 8 publications

References 10 publications

Variation in size of goat milk casein micelles related to casein genotype

Variation in size of goat milk casein micelles related to casein genotype

κ-Casein-deficient mice fail to lactate

Incorporation of32P and45Ca into milk and casein micelles of a buffalo (Bubalus bubalis) following intramuscular injection

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Incorporation of³²P and⁴⁵Ca into milk and casein micelles of a buffalo (Bubalus bubalis) following intramuscular injection