Rearing of Fabrea salina Henneguy (Ciliophora, Heterotrichida) with three unicellular feeds

The growth rate of the ciliate Fabrea salina was studied in batch cultures in the presence of three feeds, tested separately from each other: the Prymnesiophyceae, Isochrysis galbana obtained from pure culture, the Chlorophyceae Dunaliella salina, and the commercially available yeast Saccharomyces cerevisiae. F. salina, and D. salina were harvested below the surface from the first evaporation pond and the crystallizer pond, respectively in multi-pond salterns (Sfax, Tunisia). The highest density of Fabrea was recorded with I. galbana (26 ind ml(-1)). However, the greatest length (243 microm) was recorded with Fabrea fed with D. salina. The lowest density, length and biovolume values were recorded with Fabrea fed with S. cerevisiae. The ANOVA test showed that density (F=18, d.f.=57), length (F=33, d.f.=57), and biovolume (F=19, d.f.=57) of Fabrea fed with yeast were significantly different (p<0.001) from those when Fabrea was fed with D. salina and I. galbana. The ciliate Fabrea encountered in the Sfax saltern (Tunisia) might be a valuable food source for Tunisian marine fish hatcheries.     

A rhodopsin immunoanalog in the related photosensitive protozoans Blepharisma japonicum and Stentor coeruleus

Immunoblotting of isolated cell membrane fractions from ciliates Blepharisma japonicum and Stentor coeruleus with a polyclonal antibody raised against rhodopsin revealed one strong protein band of about 36 kDa, thought to correspond to protozoan rhodopsin. Inspection of both ciliates labeled with the same antibody using a confocal microscope confirmed the immunoblotting result and demonstrated the presence of these rhodopsin-like molecules localized within the cell membrane area. Immunoblot analysis of the ciliate membrane fractions resolved by two-dimensional gel electrophoresis identified two distinct 36 kDa spots at pIs of 4.5 and 7.0 for Blepharisma, and three spots at pIs of 4.4, 5.0 and 6.0 for Stentor, indicating a possible mixture of phosphorylated rhodopsin species in these cells. The obtained results suggest that both Blepharisma and the related ciliate Stentor contain within the cell membrane the rhodopsin-like proteins, which may be involved as receptor molecules in the sensory transduction pathway mediating motile photoresponses in these protists as in other species of lower eukaryota.     

Immunoreactivity of rhodopsin and opsin

An examination by a radioimmunoassay of the relative affinity of opsin and rhodopsin for rabbit antibody raised against bovine rhodopsin revealed that opsin was the preferred antigen. About 10-fold greater amounts of rhodopsin than opsin were required to achieve 50% inhibition of binding of 125I-labeled ligand in the RIA. Opsin was more reactive when examined in the light or dark, compared to rhodopsin incubated in the dark. Mixtures of opsin and rhodopsin (prepared by partial bleaching of rhodopsin or synthetic mixtures) exhibited increased reactivity with increasing mole fraction of opsin. This response was nonlinear, with small increases in opsin producing relatively large increases in reactivity. A partial fractionation of the antibody into two groups showing differential reactivities toward opsin and rhodopsin was achieved by affinity chromatography on opsin-Sepharose. However, with both groups, opsin was still the preferred antigen. Scatchard analysis of 125I-labeled rhodopsin and opsin produced nonlinear plots, indicating the presence of multiple species of antibody. The affinities and binding capacities were similar for both labeled antigens. In competitive binding studies, the antibody showed a strong preference for either labeled ligand (rhodopsin or opsin) as compared to the unlabeled material. These latter observations indicate that altering rhodopsin either by bleaching or iodination produced changes in the relative immunoreactivity of the molecule.     

Synthesis of functional bovine opsin in insect cells under control of the baculovirus polyhedrin promoter

In vitro expression of cDNA encoding bovine opsin is accomplished using the baculovirus expression vector system. Full-length opsin was synthesized which was recognized by poly- and monoclonal antisera raised against bovine rhodopsin. Upon infection with a recombinant virus, 1×10⁶ insect cells produced up to 3 g opsin. Incubation of the in vitro synthesized opsin with 11-cis retinal produced a hydroxylamine-stable, photosensitive pigment.Abbreviations dpi days post infection - pfu plaque forming units - AcNPV Autographa californica nuclear polyhedrosis virus     

Accessibility of sulfhydryl groups to 5,5'-dithiobis-2-nitrobenzoic acid and acid-base properties of bovine and walleye pollock rhodopsin preparations]

Both the number of exposed SH-groups and the rate of reaction with 5,5'dithiobis-2-nitrobenzoic acid (DTNB) in walleye pollock and bovine rhodopsin depend on a degree of native structure of the preparation to be investigated. The preparations studied can be arranged in the order of increase of these parameters as follows: ROS less than rhodopsin extracted by digitonin less than triton X-100 less than cetyltrimethylammonium bromide (CTAB) less than sodium dodecylsulphate (SDS). After illumination of ROS and digitonin, triton X-100 and CTAB-solubilized rhodopsin, and increase was observed in the number of modified SH-groups. Dark and bleached samples of walleye pollock rhodopsin exhibited a faster rate reaction and a more number of modified SH-groups as compared to bovine preparation. The differences between bovine and walleye pollock preparation disappeared after complete opsin unfolding as a result ROS solubilization in SDS. Six SH-groups per molecule of rhodopsin were modified in both preparation under these conditions. No differences in the number of cysteine residues (10--11), disulfide groups (2), acid (35--40) and base (25--30) titratable groups per rhodopsin molecule were found between bovine and walleye pollock ROS membranes. The isoelectric point of both rhodopsin preparations was within the pH range 5.2--5.6. After proteolysis of ROS with papain, a fragment with molecular weight 24500 +/- 1000 was detected, which contained the same number of SH-groups and cysteine residues as in the case of intact rhodopsin. The results obtained suggest that, in spite of a similar primary structure, the walleye pollock visual pigment has more "loose" and "fluid" space packing in the ROS membrane than the bovine pigment.     

Suitability of Selected Marine Algae for Growing the Marine Heterotrich Ciliate Fabrea salina1

ABSTRACT. Forty-five axenically grown algal (sensu lato) species representing six divisions—that is. 13 Chlorophyceae, 14 Chrysophycophyta, five Dinophycophyta, seven Cryptophycophyta, two Rhodophycophyta, and four Cyanochloronta—were aseplicaily presented separately as potential food sources to the marine helerotrich ciliate Fabrea salina under standardized algal number, medium, lighting, and temperature. The algae can be placed into three groups based on their effect on the intrinsic growth rate of the ciliate. Nutritious: Rhodomonas lens, cryptomonad LIS₁, Dunaliella parva, Prasinodadus marinus, Chroomonas salina, D. tertiolecta, Chaeloceros galvestonensis, D. primolecta, Phaeodactylum tricornutum, D. salina, Isochrysis galbana, Cylindrothecaclosterium, cryptomonad strains M₂, WH₂ & FSA, Chroomonas sp., P. lubricus, and Peridinium trochoideum. Maintamers: Cyanobacterium strain Tigriopus blue green, P. triquetum. Monochrysis lutheri, Exuviella gracilis, Platymonas tetrathele. Cyclotella caspa, Crypthecodinium cohnii, Prasinocladus C₅ strain, D. viridis, Nannochloris occulata, Tetraselmis gracilis, Anacystis marinum, Rhodosorus marinum, and Thalassiosira pseudonana. Nonnutritious: Stichococcus immobilis, Hymenomonas sp. strain 150, Syracosphaera sp. strain 181, Tetraselmis verrucosa, Thalassiosira fluviatilis, Microcoleus chthonoplastes, Synechococcus sp., Pavlova gyrans, Prymnesium parvum, Coccolithus huxleyi, Olisthodiscus luteus, Amphidinium carterii, and Porphyridium aerugineum. There was no apparent relationship between a given taxon and the nutritional value of the group, with the possible exception of the Cryptophycophyta.     

Sequence,Structure and Ligand Binding Evolution of Rhodopsin-Like G Protein-Coupled Receptors: A Crystal Structure-Based Phylogenetic Analysis

G protein-coupled receptors (GPCRs) form the largest family of membrane receptors in the human genome. Advances in membrane protein crystallization so far resulted in the determination of 24 receptors available as high-resolution atomic structures. We performed the first phylogenetic analysis of GPCRs based on the available set of GPCR structures. We present a new phylogenetic tree of known human rhodopsin-like GPCR sequences based on this structure set. We can distinguish the three separate classes of small-ligand binding GPCRs, peptide binding GPCRs, and olfactory receptors. Analyzing different structural subdomains, we found that small molecule binding receptors most likely have evolved from peptide receptor precursors, with a rhodopsin/S1PR1 ancestor, most likely an ancestral opsin, forming the link between both classes. A light-activated receptor therefore seems to be the origin of the small molecule hormone receptors of the central nervous system. We find hints for a common evolutionary path of both ligand binding site and central sodium/water binding site. Surprisingly, opioid receptors exhibit both a binding cavity and a central sodium/water binding site similar to the one of biogenic amine receptors instead of peptide receptors, making them seemingly prone to bind small molecule ligands, e.g. opiates. Our results give new insights into the relationship and the pharmacological properties of rhodopsin-like GPCRs.     

Seasonal change in a saline temporary lake (Fuente de Piedra,southern Spain)

Fuente de Piedra saline lake is located in an endorheic basin in the south of Spain. This lake is very shallow (0.5 m max. depth during 1987–88) and relatively large (± 1350 ha). It is a temporary playa lake, showing irregular cycles, with frequent seasonal drought and a high degree of unpredictability. The lake was sampled monthly during a relatively rainy year (1987–88, 10.5 months permanence). The result of combined analyses for environmental variables (salinity, temperature and soluble inorganic forms of nitrogen and phosphorus), variables related to biological activity (chlorophyll a, sediment organic matter and redox potential) and the direct analysis of the planktonic community, shows the existence of two periods of dominance by autotrophs. The first occurs during winter, exhibits a progressively higher surface to volume ratio for phytoplankton and is followed in the spring by high zooplankton densities (Moina salina, Fabrea salina) and very low phytoplankton densities, suggesting the existence of a period with a detritus-based food web. The summer period coincides with a community better adapted to high salinities that is dominated by Dunaliella salina, D. viridis, diatoms and the ciliate Fabrea salina, and associated with high ammonium concentrations. A new period of organic matter accumulation could be facilitated, in the last moments before the lake dries, by a progressive decrease in zooplankton abundance.     

Excited-state dynamics of all-trans protonated retinal Schiff base in CRABPII-based rhodopsin mimics

The rhodopsin mimic is a chemically synthetized complex with retinyl Schiff base (RSB) formed between protein and the retinal chromophore that can mimic the natural rhodopsin-like protein. The artificial rhodopsin mimic is more stable and designable than the natural protein and hence has wider uses in photon detection devices. The mimic structure RSB, like the case in the actual rhodopsin-like protein, undergoes isomerization and protonation throughout the photoreaction process. As a result, understanding the dynamics of the RSB in the photoreaction process is critical. In this study, the ultrafast transient absorption spectra of three mutants of the cellular retinoic acid-binding protein II-based rhodopsin mimic at acidic environment were recorded, from which the related excited-state dynamics of the all-trans protonated RSB (AT-PRSB) were investigated. The transient fluorescence spectra measurements are used to validate some of the dynamic features. We find that the excited-state dynamics of AT-PRSB in three mutants share a similar pattern that differs significantly from the dynamics of 15-cis PRSB of the rhodopsin mimic in neutral solution. By comparing the dynamics across the three mutants, we discovered that the aromatic residues near the β-ionone ring structure of the retinal may help stabilize the AT-PRSB and hence slow down its isomerization rate. The experimental results provide implications on designing a rhodopsin-like protein with significant infrared fluorescence, which can be particularly useful in the applications in biosensing or bioimaging in deeper tissues.     

The molar extinction of rhodopsin

The molar extinction of rhodopsin is 40,600 cm.² per mole equivalent of retinene; i.e., this is the extinction of a solution of rhodopsin which is produced by, or yields on bleaching, a molar solution of retinene. The molar extinctions of all-trans retinene and all-trans retinene oxime have also been determined in ethyl alcohol and aqueous digitonin solutions. On the assumption that each chromophoric group of rhodopsin is made from a single molecule of retinene, it is concluded that the primary photochemical conversion of rhodopsin to lumi-rhodopsin has a quantum efficiency of 1; though the over-all bleaching of rhodopsin in solution to retinene and opsin may have a quantum efficiency as low as one-half. On bleaching cattle rhodopsin, about two sulfhydryl groups appear for each molecule of retinene liberated. In frog rhodopsin the —SH:retinene ratio appears to be higher, 5:2 or perhaps even 3:1. Some of this sulfhydryl appears to have been engaged in binding retinene to opsin; some may have been exposed as the result of changes in opsin which accompany bleaching, comparable with protein denaturation.     

Synthesis of 11-cis-locked bicyclo[5.1.0]octanyl retinal and an enantioselective binding to bovine opsin

Both enantiomers of 13-(E) and 13-(Z) isomers of 11-cis-locked bicyclo[5.1.0]octanyl retinal were prepared by an improved synthesis and incubated with bovine opsin. The synthesis also establishes the absolute configuration of the enantiomers. Only one of the enantiomers binds to opsin, thus showing the steric restrictions regarding the middle polyene moiety of the retinoid molecule; this is in sharp contrast to the known leniency of the ring moiety binding site of retinoids. However, although one enantiomer is incorporated into the pigment, the circular dichroic spectrum of the pigment incorporating the bound enantiomer yields only a very weak Cotton effect, showing that, once incorporated, the bicyclo[5.1.0]octanyl chromophore is flattened by the opsin binding site. The titled retinoid was synthesized for study of the absolute conformation of the retinal pigment in rhodopsin.     

Slow bleach-induced cooperative fluorescence changes in bovine photoreceptor disk membranes

The increase of protein fluorescence in suspensions of bovine photoreceptor disk membrane fragments was investigated under various conditions. The increment of fluorescence on bleaching was dependent on temperature, being about 10% at 10°C and 50% at 40°C. The time course of fluorescence increase also depended on temperature, and the activation energy was estimated to be about 14 kcal/mole. The relationship between the extent of fluorescence increase and the degree of bleaching was not stoichiometric. It was concluded that the environment of tryptophan residues of unbleached rhodopsin molecule(s) located near a bleached rhodopsin molecule is cooperatively modified upon bleaching (to a more hydrophobic environment).     

Differential Rhodopsin Regeneration in Photoreceptor Membranes is Correlated with Variations in Membrane Properties

Rhodopsin, the major transmembrane protein in both the plasma membrane and the disk membranes of photoreceptor rod outer segments (ROS) forms the apo-protein opsin upon the absorption of light. In vivo the regeneration of rhodopsin is necessary for subsequent receptor activation and for adaptation, in vitro this regeneration can be followed after the addition of 11-cis retinal. In this study we investigated the ability of bleached rhodopsin to regenerate in the compositionally different membrane environments found in photoreceptor rod cells. When 11-cis retinal was added to bleached ROS plasma membrane preparations, rhodopsin did not regenerate within the same time course or to the same extent as bleached rhodopsin in disk membranes. Over 80% of the rhodopsin in newly formed disks regenerated within 90 minutes while only 40% regenerated in older disks. Since disk membrane cholesterol content increases as disks are displaced from the base to the apical tip of the outer segment, we looked at the affect of membrane cholesterol content on the regeneration process. Enrichment or depletion of disk membrane cholesterol did not alter the % rhodopsin that regenerated. Bulk membrane properties measured with a sterol analog, cholestatrienol and a fatty acid analog, cis parinaric acid, showed a more ordered, less fluid, lipid environment within plasma membrane relative to the disks. Collectively these results show that the same membrane receptor, rhodopsin, functions differently as monitored by regeneration in the different lipid environments within photoreceptor rod cells. These differences may be due to the bulk properties of the various membranes.     

Evolution of opsin genes reveals a functional role of vision in the echolocating little brown bat (Myotis lucifugus)

Echolocating bats are able to orientate, navigate and forage without visual cues. To probe the role of vision in bats, we studied the visual opsin genes from the echolocating little brown bat (Myotis lucifugus). Short-wavelength sensitive (SWS1) opsin, middle/long-wavelength sensitive (M/LWS) opsin and rhodopsin cDNA sequences were identified from the Ensembl database and validated by the sequencing of genomic DNA. We retrieved the published orthologous genes from eleven additional representative species of mammals from GenBank and conducted an evolutionary analysis. We found that the M/LWS opsin and rhodopsin genes were both under strong purifying selection, whereas the SWS1 opsin gene has undergone positive selection at two amino acid sites and one lineage, though the main evolutionary force is still purifying selection. Two-ratio model of the SWS1 opsin gene revealed that the ω ratio for the little brown bat lineage was nearly three times lower than the background ratio, suggesting a much stronger functional constraint. Our relative rate tests show the little brown bat has a lower nonsynonymous substitution rate than those in other mammals (on average 32% lower) for the SWS1 opsin gene. However, no such significant differences were detected for the M/LWS opsin and rhodopsin genes. The results of the relative ratio tests are consistent with that of tests for selection, showing a history of purifying selection on the little brown bat opsin genes. These findings suggest a functional role of vision in the little brown bat despite being nocturnal and using echolocation. We speculate that this echolocating bat may be able to use visual cues to orientate, navigate and forage at night, to discriminate color under moonlight and starlight conditions, or to avoid predation by diurnal raptors.     

A radioimmunoassay specific for opsin

A radioimmunoassay is developed for bovine opsin using a rabbit antiserum against bovine rod outer segment membranes. The assay is specific for opsin. Rhodopsin, bacteriorhodopsin and hemoglobin do not show cross-reaction. It can be carried out rapidly, has a sensitivity of 0.01 pmol bovine opsin and gives accurate results, even in the presence of a large excess of rhodopsin. Under the conditions described, the assay can be used to measure bovine opsin and rhodopsin in each other's presence by running a sample before and after illumination, with a sensitivity 2000-times higher than with spectrophotometric methods. The opsin content of rather crude preparations such as bovine retina homogenates can be accurately determined. Rabbit and mouse opsin can also be assayed with a reasonable degree of accuracy using the same rabbit antiserum.     

Biochemical aspects of the visual process XXVIII. Classification of sulfhydryl groups in rhodopsin and other photoreceptor membrane proteins

Reaction of isolated bovine rod outer segment membrane with radioactiveN-ethylmaleimide, both in the presence and absence of 1% dodecyl sulfate followed by dodecyl sulfate-polyacrylamide gel electrophoresis, shows that six sulfhydryl groups (96% of total sulfhydryl in this membrane) are located on the rhodopsin molecule.On the basis of their reactivity towardsp-chloromercuribenzoate andp-chloromercuribenzene sulfonate in suspensions of outer segment membranes, the sulfhydryl groups of rhodopsin can be divided into three pairs. One pair is rapidly modified, both in light and darkness. This modification does not impair the recombination capacity of opsin with 11-cis retinaldehyde under regeneration of rhodopsin. A second pair is modified upon prolonged interaction with thep-chloromercuriderivatives in darkness. Modification of this pair leaves the typical rhodopsin absorbance at 500 nm intact, but a proportional loss of recombination capacity does occur. The third pair is only modified after illumination and is probably located in the vicinity of the chromophoric center.The difference between these results and those obtained by modification with dithiobis-(2-nitrobenzoic acid) orN-ethylmaleimide in suspension, where even upon prolonged exposure to light as well as in darkness only two sulfhydryl groups of rhodopsin are modified, is explained by the detergent-like character of thep-chloromercuri-derivatives.     

The role of sulfhydryl groups in the bleaching and synthesis of rhodopsin

The condensation of retinene₁ with opsin to form rhodopsin is optimal at pH about 6, a pH which favors the condensation of retinene₁ with sulfhydryl rather than with amino groups. The synthesis of rhodopsin, though unaffected by the less powerful sulfhydryl reagents, monoiodoacetic acid and its amide, is inhibited completely by p-chloromercuribenzoate (PCMB). This inhibition is reversed in part by the addition of glutathione. PCMB does not attack rhodopsin itself, nor does it react with retinene₁. Its action in this system is confined to the —SH groups of opsin. Under some conditions the synthesis of rhodopsin is aided by the presence of such a sulfhydryl compound as glutathione, which helps to keep the —SH groups of opsin free and reduced. By means of the amperometric silver titration of Kolthoff and Harris, it is shown that sulfhydryl groups are liberated in the bleaching of rhodopsin, two such groups for each retinene₁ molecule that appears. This is true equally of rhodopsin from the retinas of cattle, frogs) and squid. The exposure of new sulfhydryl groups adds an important element to the growing evidence that relates the bleaching of rhodopsin to protein denaturation. The place of sulfhydryl groups in the structure of rhodopsin is still uncertain. They may be concerned directly in binding the chromophore to opsin; or alternatively they may furnish hydrogen atoms for some reductive change by which the chromophore is formed from retinene₁. In the amperometric silver titration, the bleaching of rhodopsin yields directly an electrical variation. This phenomenon may have some fundamental connection with the role of rhodopsin in visual excitation, and may provide a model of the excitation process in general.     

Accessibility of the iodopsin chromophore

Iodopsin can replace its chromophore (11-cis retinal) by added 9-cis retinal, resulting in the formation of isoiodopsin. NaBH₄ bleaches iodopsin in the dark. In a relatively low concentration of digitonin, the scotopsin (the protein moiety of chicken rhodopsin) removes 11-cis retinal from isopsin in the iodopsin These facts suggests that the linkage of the chromophore to opsin in the iodopsin molecule (presumably a Schiff-base linkage) is accessible to these reagents, which is different from the situation in rhodopsin.     

Reversible phosphorylation of opsin induced by irradiation of blowfly retinae

Summary Light-induced phosphorylation and dephosphorylation of the visual pigment protein, opsin, was investigated in isolated retinae of the blowfly making use of the fact that photon capture by rhodopsin leads to the formation of a thermostable metarhodopsin. Retinae were exposed, in the presence of exogenous³²P-orthophosphate, to an intense blue light which initiated the phosphorylation of opsin (half-time about 5 min at 25 °C). Subsequent exposure of the retina to red light converted all the metarhodopsin present into rhodopsin and triggered a relatively rapid dephosphorylation of rhodopsin (half-time less than 20 s). It is proposed that the phosphorylated forms of rhodopsin and metarhodopsin represent inactive states of the pigment, i.e. phosphorylated metarhodopsin does not initiate reactions leading to the excitation of the photoreceptor cell and phosphorylated rhodopsin cannot be converted into physiologically active metarhodopsin without first being dephosphorylated.Abbreviations R1–6 peripheral retinula cells of the blowfly ommatidium - PDA prolonged depolarizing afterpotential - R rhodopsin - M metarhodopsin - R-P _n phosphorylated rhodopsin - M-P _n phosphorylated metarhodopsin - SDS-PAGE sodium dodecylsulphate polyacrylamide gel electrophoresis     

Circular dichroism,optical rotatory dispersion,and absorption studies on the conformation of bovine rhodopsin in situ and solubilized with detergent

Circular dichroism, optical rotatory dispersion and absorption of rhodopsin, the visual pigment of bovine rod outer segment membranes, were studied in situ and in membranes solubilized with various detergents. The -helical content of the membrane protein is approximately 30%. The membrane protein possesses little -structure. Solubilization of the membrane by the detergents, Emulphogene BC-720 and cetyltrimethylammonium salts, results in loss of protein helical structure and perturbation of aromatic residues. These effects are not observed on digitonin solubilization.In regard to the structural stability of the membrane during bleaching, the following conclusions were reached: (1) Delocalized conformational changes of rhodopsin in situ involving secondary and/or tertiary structure are very unlikely. (2) Localized conformational changes of rhodopsin in situ involving secondary structure must be limited to the involvement of no more than three amino acid residues and localized conformational changes involving tertiary structure must be limited to very short segments of the protein chain containing, at the most, only a few aromatic residues. (3) Large changes in the interaction of lipid and protein moieties of the membrane are unlikely. (4) The detergents, Emulphogene, cetyltrimethylammonium salts, and digitonin, significantly decrease the conformational stability of rhodopsin as compared to the in situ conditions. The effect is smaller with digitonin.Evidence is presented against a proposed mechanism by which optical activity of the prosthetic group, retinal, is induced by resonance coupling of the transition dipoles of retinal and the lowest energy transitions of the aromatic groups of the apoprotein, opsin. A mechanism in which atropisomers of retinal are preferentially bound by opsin is consistent with the present results. The optical activity of the prosthetic group is markedly changed upon solubilization of the membrane by detergent. This change in optical activity is probably coupled to changes in conformation of the protein moiety induced by solubilization.This work is based in part upon a Ph.D. dissertation submitted by C.N.R. to The Ohio State University (1974). A preliminary report of this work was presented at the sixteenth annual meeting of the Biophysical Society, Toronto, Canada, February, 1972, Abstracts SaPM-H8 and SaPM-H9