Double staining of immunoblot using enzyme histochemistry and India ink.

Immunoblotting is a commonly used technique for the immunodetection of specific proteins which have been fractionated by polyacrylamide gel electrophoresis. We describe here a simple procedure for the double staining of immunoblots, first to detect the immunoreactive component(s) by histochemistry using enzyme-conjugated secondary antibodies, and second to visualize the general protein electrophoretogram using India ink. This procedure permits the direct comparison of electrophoretic mobilities between the immunoreactive protein(s) and the total protein population as well as protein standards of known Mr. The experimental advantage of the procedure is that no additional manipulation of the protein samples or the standards is necessary prior to electrophoretic fractionation. In this report, detection of the vitamin D-dependent calcium-binding protein, calbindin-D28K, is used to illustrate the application of the procedure.     

India ink staining of proteins on nitrocellulose paper

India ink staining of proteins that have been electrotransfer blotted onto nitrocellulose paper is described. This stain proved to be a useful adjunct to the enzyme-linked immunoelectrotransfer blot technique. It is more sensitive than Coomassie blue, amido black, and fast green stains and is simple to use.     

India ink staining of proteins on nylon and hydrophobic membranes

India ink was found to be an acceptable stain for proteins blotted or dotted onto positively charged nylon or hydrophobic membranes. The hydrophobic membrane, Immobilon, was an outstanding matrix for binding proteins and displayed low levels of background staining. The least amount of protein detected by india ink staining was between 1.0 and 10 ng. India ink staining of proteins on nylon membranes is an easy, inexpensive, and quick method for the unequivocal detection of both standards and unknowns in the same blot. However, inks, ink concentrations, fixing conditions, staining times, pH, washing conditions, and membrane lots all need to be controlled to achieve maximum sensitivity for protein detection following india ink staining.     

Uptake of India ink particles and latex beads by corneal fibroblasts

Summary The fate of India ink particles and polystyrene latex beads injected into the corneal stroma of rabbits was studied by the naked eye, light microscopy, and electron microscopy. All the injected ink particles or latex beads were unchanged in shape, size, and number for at least 6 months. India ink particles and latex beads were endocytosed by the corneal fibroblasts within 3–4 days after injection. Numerous ink particles were packed into vacuoles, 0.5–10 m in diameter, which occupy a large volume of the cytoplasm of the cell body and processes of fibroblasts in and near the injected area. Each latex bead, 0.72 m in diameter, is usually enclosed in one vesicle, and a large number of vesicles are distributed throughout the cytoplasm. In corneal tissue removed 10 min after injection of India ink and cultured for 3 or 7 days, uptake of many ink particles by the fibroblasts was seen. By this experiment, the contribution of the blood-derived cells was completely excluded, and it is more distinctly shown that the corneal fibroblast has a strong endocytotic activity.The uptake and long-term storage of ink particles and latex beads by the corneal fibroblast are reactions that protect the organ without inflammation from the injury and harm by non-toxic foreign materials.A part of this study was published in Kinki Daigaku Igaku Zasshi in Japanese as a Ph. D. thesis by Atsuko Ueda. This study was supported by grants from the Ministry of Education, Science and Culture, Japan, the Osaka Eye Bank, Osaka, Japan, and an intramural Research Fund of Kinki University, Japan     

Fixation increases sensitivity of India ink staining of proteins and peptides on nitrocellulose paper

The detectability by India ink staining of proteins and peptides dot-blotted on nitrocellulose paper was assessed before and after fixation. Fixation considerably increased the detectability of proteins and peptides. Denaturation by KOH treatment or baking at 100 degrees C for 15 min gave the best results. Precipitation by isopropanol/acetic acid gave intermediate results, whereas crosslinking with glutaraldehyde improved the detectability of small peptides, but not of proteins. Ferridye and Aurodye were also tested after baking. Both dyes were more sensitive and stained more proteins and peptides than India ink. In all cases the detectability of peptides smaller than Mr 1500 was poor.     

Quantification of proteins in the subnanogram and nanogram range: comparison of the AuroDye, FerriDye, and India ink staining methods

The usefulness of three sensitive dyes, AuroDye, FerriDye, and India ink, for the quantification of proteins and peptides bound to nitrocellulose paper has been assessed. In general, the staining intensity varies linearly with the logarithm of protein concentrations. The detection limit of small peptides (Mr less than 5000) is higher than that of large peptides and proteins, but the sensitivity is independent of the molecular weight. Oligopeptides of four or less amino acids either stain with very high detection limits or do not stain at all. The detection limit of proteins stained by AuroDye is approximately 1 ng, and in a number of cases even lower. The useful range for quantification of proteins extends to around 100 ng. The FerriDye and India ink staining methods are less sensitive and can be used to quantify proteins over a wide nanogram range. Among the methods tested, the India ink staining method has the highest protein to protein variation in sensitivity.     

曼氏无针乌贼墨囊组织学及墨汁形成的超微结构

采用组织学和电镜技术对曼氏无针乌贼的墨囊及墨腺细胞进行了研究。结果表明:墨囊壁和导管壁由外膜、肌肉层和黏膜三部分组成;墨腺体集中在墨囊底部,呈索状,腺体中部含丰富的结缔组织;墨汁颗粒以游离态形式分布于索状腺体的间隙及墨囊腔中。实验观察到无分泌黑色素功能的A型细胞和有分泌黑色素功能的B型细胞;在B型细胞中可见黑色素颗粒储存在囊泡中,囊泡在移出细胞的过程中逐渐变大,泡内的黑色素颗粒逐渐变多。囊泡可能通过胞吐的方式排出细胞外,黑色素排出后以颗粒的形式游离于细胞间隙中,形成墨汁。     

Effect of splenectomy and India ink blockade of Kupffer cells on hepatocyte mitotic activity following hepatectomy]

Splenectomy was carried out in one group of rats 48 hours before partial hepatectomy. The second group was given an injection of 2 ml of a 1% India ink solution into the spleen for the purpose of block of the reticulo-endothelial system of the liver four days before partial hepatectomy. An increase of the mitotic activity of hepatocytes occurred in both experimental groups at later periods than in control ones.     

Melanogenesis in the ink gland of Sepia officinalis

Among the various melanin-producing systems, the ink gland of the cuttlefish (Sepia officinalis) has traditionally been regarded as a most convenient model system for the studies of melanogenesis. The ink gland is a highly specialized organ with immature cells in the inner portion, from where the cells gradually mature, migrate towards the outer portion of the gland and become competent to produce melanin giving rise to particulate melanosomes. When cell maturation is complete, melanin is secreted into the lumen of the gland, accumulated into the ink sac and ejected on demand. Biochemical studies carried out over the past two decades have shown that the ink gland contains a variety of melanogenic enzymes, including tyrosinase, a peculiar dopachrome rearranging enzyme (which catalyses the rearrangement of dopachrome to 5,6-dihydroxyindole) and a peroxidase (presumably involved in the later stages of melanin biosynthesis). These enzymes are functionally interactive in close subcellular compartments of ink gland cells and appear to act in a concerted fashion during the process of melanogenesis in the mature portion of the gland. More recent studies have revealed that ink production and ejection are affected and modulated by the N-methyl-D-aspartate (NMDA)-nitric oxide (NO)-cyclic GMP (cGMP) signalling pathway. Glutamate NMDA receptor and NO synthase, the enzyme responsible for the synthesis of NO, have been detected by biochemical and immunohistochemical techniques in immature ink gland cells. Stimulation of NMDA receptors caused a marked elevation of cGMP levels, activation of tyrosinase and increased melanin synthesis in the mature portion of the gland, via the NO-guanylyl cyclase interaction. This signalling is also present in different regions of the nervous system in Sepia and in certain neural pathways controlling contraction of the ink sac sphincters and wall muscle in the ejection mechanism. Overall, these and other findings allowed elaboration of an improved model of melanin formation in Sepia, which underscores the complex interplay of melanogenic enzymes and regulatory factors, highlighting both the similarities and the differences with melanogenesis in mammals.