Chlorophyll b is involved in long-wavelength spectral properties of light-harvesting complexes LHC I and LHC II.

Chlorophyll (Chl) molecules attached to plant light-harvesting complexes (LHC) differ in their spectral behavior. While most Chl a and Chl b molecules give rise to absorption bands between 645 nm and 670 nm, some special Chls absorb at wavelengths longer than 700 nm. Among the Chl a/b-antennae of higher plants these are found exclusively in LHC I. In order to assign this special spectral property to one chlorophyll species we reconstituted LHC of both photosystem I (Lhca4) and photosystem II (Lhcb1) with carotenoids and only Chl a or Chl b and analyzed the effect on pigment binding, absorption and fluorescence properties. In both LHCs the Chl-binding sites of the omitted Chl species were occupied by the other species resulting in a constant total number of Chls in these complexes. 77-K spectroscopic measurements demonstrated that omission of Chl b in refolded Lhca4 resulted in a loss of long-wavelength absorption and 730-nm fluorescence emission. In Lhcb1 with only Chl b long-wavelength emission was preserved. These results clearly demonstrate the involvement of Chl b in establishing long-wavelength properties.     

Assembly of the Light-Harvesting Complexes (LHCs) of Photosystem II (Monomeric LHC IIb Complexes Are Intermediates in the Formation of Oligomeric LHC IIb Complexes)

The light-induced assembly of light-harvesting complex (LHC) II has been followed during the biogenesis of the plastid. Seedlings grown in intermittent light (IML) accumulate only small amounts of chlorophyll b. The minor LHC II apoproteins are present; however, the apoprotein levels of the major LHC II complex, LHC IIb, are severely depressed after exposure to IML. The levels of all LHC II apoproteins increase rapidly upon exposure to continuous illumination. The 25-kD, type 3 LHC IIb subunit appears to be more abundant during the early hours of greening in relation to its level in mature thylakoids. The LHC IIb apoproteins are initially associated with pigments to form monomeric pigment-protein complexes. The abundance of monomeric LHC IIb complexes gradually decreases during exposure to continuous light and a concomitant increase occurs in the amount of the trimeric and higher-order oligomeric forms. Pulse-chase experiments verify that labeled LHC IIb monomeric complexes are intermediates in the formation of trimeric and higher-order oligomeric LHC IIb-pigmented complexes. Therefore, the assembly of LHC II occurs via the initial pigmentation of the apoproteins to form monomeric complexes and proceeds in a sequential manner.     

Red algal LHC I genes have similarities with both Chl a/b- and a/c-binding proteins: A 21 kDa polypeptide encoded by LhcaR2 is one of the six LHC I polypeptides

Polypeptides from the PS I holocomplex of the red alga P. cruentum, purified for microsequencing, confirmed that six LHC I polypeptides from SDS-PAGE are distinct apoproteins. Analysis of a cDNA clone, designated as LhcaR2, from a cDNA library, indicates that it shares major structural features with the recently cloned first red algal gene LhcaR1. The LhcaR2 is believed to encode the 21.0 kDa polypeptide of the LHC I complex from comparison of the deduced amino acid sequence and the microsequences of several tryptic digest fragments from the isolated polypeptide. As in chlorophytic and chromophytic LHCs, the essential residues for Chl-binding and helix stabilization in helices 1 and 3 are highly conserved. Relatedness between rhodophytes and the chlorophytes is also inferred from sequence conservation in the N-flanking regions of helices 1 and 3. Conversely, helix 2 exhibited the highest similarity between LHC sequences of Chl a/c-binding chromophytes and the Chl a-binding rhodophytes, with 11 of 22 residues identical or conservatively substituted. Moreover, whereas in chlorophytes, the Q and E Chl-binding residues are separated by seven amino acid residues, they are always separated by 8 residues in rhodophytes and chromophytes. Superimposition of the predicted LhcaR2 sequence with the LHC II model [Kühlbrandt et al. (1994) Nature 367: 614–621] shows the same structural features except shortened connecting sequence between helices 1 and 2 on the lumenal side. The chimeric nature of rhodophyte genes, with both chromophytic and chlorophytic features, leads to the suggestion that they reflect attributes of an intermediate stage in LHC apoprotein evolution.     

Monoclonal antibodies specific for the light-harvesting chlorophyll a/b-protein complex (LHC): Detection of conserved antigenic determinants in LHC from different species

Monoclonal antibodies have been raised against the light-harvesting chlorophyll a/b-protein complex (LHC) of pea and characterised using the enzyme linked immunosorbent assay (with purified LHC or intact thylokoids) or immunoblotting using chloroplast proteins transferred from SDS-PAGE gels. Several clones showed strong binding to the two major polypeptides of pea LHC, even after trypsin or proteinase K treatment. The two antibodies with the most efficient binding to pea LHC were shown to cross-react with polypeptides from green algae and higher plants; indicating sequential similarities and the presence of several closely related polypeptides between phylogenetically distant species.     

Evolutionary conservation of the chlorophyll a/b-binding proteins: cDNAs encoding type I, II and III LHC I polypeptides from the gymnosperm Scots pine

Summary cDNAs encoding three different LHC I polypeptides (Type I, Type II and Type III) from the gymnosperm Scots pine (Pinus sylvestris L.) were isolated and sequenced. Comparisons of the deduced amino acid sequences with the corresponding tomato sequences showed that all three proteins were highly conserved although less so than the LHC II proteins. The similarities between mature Scots pine and tomato Types I, II and III LHC I proteins were 80%, 87% and 85%, respectively. Two of the five His residues that are found in AXXXH sequences, which have been identified as putative chlorophyll ligands in the Type I and Type II proteins, were not conserved. The same two regions of high homology between the different LHC proteins, which have been identified in tomato, were also found in the Scots pine proteins. Within the conserved regions, the Type I and Type II proteins had the highest similarity; however, the Type II and Type III proteins also showed a similarity in the central region. The results suggest that all flowering plants (gymnosperms and angiosperms) probably have the same set of LHC polypeptides. A new nomenclature for the genes encoding LHC polypeptides (formerly cab genes) is proposed. The names lha and lhb are suggested for genes encoding LHC I and LHC II proteins, respectively, analogous to the nomenclature for the genes encoding other photosynthetic proteins.     

Taxonomic distribution and origins of the extended LHC (light-harvesting complex) antenna protein superfamily

Background  

The extended light-harvesting complex (LHC) protein superfamily is a centerpiece of eukaryotic photosynthesis, comprising the LHC family and several families involved in photoprotection, like the LHC-like and the photosystem II subunit S (PSBS). The evolution of this complex superfamily has long remained elusive, partially due to previously missing families.     

Deoxyribonuclease I (DNase I)

A number of phosphodiesterases, some of which possess additional biological activities (e.g., antitumor, immunosupressive, and so on), have been considered for use in targeted tumor therapy. We propose Deoxyribonuclease I (DNase I), a compact, monomeric enzyme, as a very attractive candidate for targeting to tumor cells. Only a small amount of enzyme targeted to a cell needs to enter the nucleus in order to degrade the chromosomal DNA, making a cell incapable of further replication. We describe preliminary data on the construction of a potent single-chain antibody (scFv) immunotoxin based on bovine pancreatic DNase I. The use of a mammalian enzyme should be much less toxic and less immunogenic than current immunotoxins and may expand the current limits of immunotoxin therapy.     

Correlation between pigment composition and apoproteins of the light-harvesting complex II (LHC II) in wheat (Triticum aestivum)

Seedlings of wheat (Triticum aestivum L. cv. Walde, Weibull) grown in continuous weak red light (16 mW m⁻²) with or without SAN-9789, contained significantly lower amounts of chlorophylls and carotenoids compared to untreated plants grown in a greenhouse. The Chl alb ratios were 3.6 in the greenhouse-grown plants, 5.1 in untreated and ca 16 in SAN-treated plants grown in weak red light, respectively. The main difference in polypeptide composition of thylakoids isolated from red light-grown plants, compared to those grown in the greenhouse, was a lower amount of proteins of the light-harvesting complex (LHC) II. The amount of apo-LHC and LHC were correlated to the xanthophyll to β-carotene ratios in these plants. The absence of grana and the absence of proteins of the light-harvesting complex 11 in SAN-treated plants, support the general dogma that these proteins are involved in the formation of grana. Since the amount of apo-LHC and LHC could be correlated to the presence of carotenoids as well as the chlorophylls, it is concluded that the carotenoids are necessary for the correct assembly and stabilization of the apoproteins of LHC II in the thylakoid membranes.     

Selective inhibition of the spinach thylakoid LHC II protein kinase

Treatment of spinach thylakoids with the adenosine affinity inhibitor 5′-p-fluorosulfonylbenzoyl adenosine (FSBA) resulted in at least 95% inhibition of phosphorylation of the light-harvesting protein complex of Photosystem II (LHC II), while the M_r 10 000 polypeptide showed a 35% decrease in phosphorylation. This residual kinase activity after FSBA treatment appears to have the same properties as the control, since phosphorylation of the M_r 10 000 polypeptide subsequent to FSBA treatment could be achieved with either light or reducing conditions in the dark. [¹⁴C]FSBA labelled several polypeptides, but only the M_r 50 000 band was protected against the label by prior addition of ADP or adenosine, making it a possible candidate for the LHC II kinase. FSBA had no effect on electron transport, and [¹⁴C]FSBA did not label LHC II or the M_r 10 000 polypeptide, indicating that the FSBA was not interfering with activation of the kinase or modifying the substrates, but rather acting at the level of the LHC II protein kinase. Inhibition of LHC II phosphorylation by FSBA resulted in the elimination of the slow ATP-induced decrease in variable fluorescence, a parameter believed to be associated with phosphorylation of the LHC II. The half-times and time-course for inhibition of LHC II phosphorylation and inhibition of the ATP-induced decrease of fluorescence yield were identical, consistent with the concept that LHC II phosphorylation plays a major role in this fluorescence change.     

Occurrence of the carotenoid lactucaxanthin in higher plant LHC II

The pigment composition of the light-harvesting complexes of Photosystem II (LHC II) has been determined for lettuce (Lactuca sativa). In common with other members of the composite, the photosynthetic tissues of this species may contain large amounts of the carotenoid lactucaxanthin (, -carotene-3,3'-diol) in addition to their normal compliment of carotenoids. The occurrence and distribution of lactucaxanthin in LHC II has been examined using isoelectric focusing of BBY particles followed by reversed-phase HPLC analysis of the pigments. The major carotenoids detected in LHC IIb, LHC IIa (CP29) and LHC IIc (CP26) purified from dark-adapted lettuce were lutein, violaxanthin, neoxanthin and lactucaxanthin. Lactucaxanthin has been shown to be a major component of PS II, accounting for 26% of total xanthophyll in both LHC IIb (23% total xanthophyll) and in the minor complexes (12–16%). In this study, LHC IIb was clearly resolved into four bands and their carotenoid composition determined. These four bands proved to be very similar in their pigment content and composition, although the relative amounts of neoxanthin and lutein in particular were found to increase from bands 1 to 4 (i.e. with increasing electrophoretic mobility). The operation of the xanthophyll cycle has also been examined in the LHC of L. sativa following light treatment. The conversion efficiency for violaxanthinzeaxanthin was nearly identical for each light-harvesting complex examined at 58–61%. Nearly half of the zeaxanthin formed in PS II was associated with LHC IIb, although the molar ratio of zeaxanthin:chlorophyll a was highest in the minor LHC.Abbreviations HPLC high performance liquid chromatography - IEF isoelectric focusing - LHCII light-harvesting complex associated with Photosystem II - PS II Photosystem II - qE pH-dependent nonphotochemical quenching of chlorophyll fluorescence     

Thylakoid-bound proteolytic activity against LHC II apoprotein in bean

Triton X-100 solubilized thylakoids, isolated from Phaseolus vulgaris chloroplasts, degrade endogenous or exogenously added LHC II. The degradation, as monitored by immunodetection of the remaining LHC II after incubation at 37°C, is activated by Mg⁺⁺ and inhibited by pCMB, EDTA, PMSF and benzamidine; the activity under high light conditions parallels chlorophyll photooxidation. The thylakoid-bound proteolytic activity is under phytochrome control. Etiolated plants pretreated by a white light pulse, and kept in the dark thereafter, show enhanced proteolytic activity, which follows rhythmical oscillations. On the other hand, chloramphenicol pretreatment of etiolated plants, prior to their transfer to continuous light, reduces the proteolytic activity against LHC II. The results suggest that the degradation involves a serine type protease, which depends on SH group(s), coded by the plastid genome; the protease action on LHC II is regulated by Mg⁺⁺, phytochrome, the biological clock and chlorophyll accumulation in the thylakoid. The stroma lamellar fraction, separated from French press disrupted chloroplasts, exhibits higher activity towards exogenous LHC II than the grana fraction. The stroma of intact chloroplasts exhibits also high proteolytic activity, which is drastically reduced when the lysis medium is supplemented with cations. This suggests that the protease is bound mainly on stroma lamellae and peripheral granal membranes, its association to the membranes being possibly under cation control.Abbreviations CAP chloramphenicol - CL continuous light - LHC II light harvesting complex of Photosystem II     

Structure of poly (I).poly (A).poly (I)

The molecular structure of poly (I).poly (A).poly (I) has been determined and refined using the continuous intensity data on layer lines in the x-ray diffraction pattern obtained from an oriented fiber of this polymorphic RNA complex. The polymer forms a 12-fold right-handed triple-helix of pitch 39.7A and each base-triplet is stabilized by quasi Crick-Watson-Hoogsteen hydrogen bonds. The ribose rings in all the three strands have C3'-endo conformations. The final R-value for this best structure is 0.24 and the x-ray fit is significantly superior to all the alternative structures where the different chains might have different furanose conformations. This all-purine triple-helix, counter-intuitively, has a diameter roughly 3A shorter than that of DNA and RNA triple-helices containing a homopurine and two complementary homopyrimidine strands. Its compact, grooveless cylindrical shape is consistent with the lack of lateral organization.     

Central-Cis isomers of lutein found in the major light-harvesting complex of Photosystem II (LHC IIb) of higher plants

Lutein (,-carotene-3,3-diol) is the major carotenoid of the light-harvesting systems of higher plants. Lutein was isolated at 4°C and in complete darkness from the bulk light-harvesting complex of Photosystem II of spinach (LHC IIb) and from BBY particles. Separation using normal-phase HPLC (with 2D detection) in comparison to the authentic isomers (prepared by iodine-sensitised isomerization) showed the presence of a number of geometrical isomers of this xanthophyll in PS II, namely all-trans (the major component); 13-cis, 13-cis and 15-cis-lutein. Iodine-sensitised photo-isomerization of all-trans lutein produced six geometrical isomers of lutein as determined by HPLC. The configuration of five of these isomers was determined by ¹H-NMR to be all-trans, 9-cis, 9-cis, 13-cis and 13-cis. In addition, small amounts of another isomer have been tentatively identified to be 15-cis lutein on the basis of its electronic absorption spectrum. The possible functional significance of the presence of cis-isomers of this carotenoid in LHC IIb is discussed.     

Complete primary structure of rainbow trout type I collagen consisting of alpha1(I)alpha2(I)alpha3(I) heterotrimers.

The subunit compositions of skin and muscle type I collagens from rainbow trout were found to be alpha1(I)alpha2(I)alpha3(I) and [alpha1(I)](2)alpha2(I), respectively. The occurrence of alpha3(I) has been observed only for bonyfish. The skin collagen exhibited more susceptibility to both heat denaturation and MMP-13 digestion than the muscle counterpart; the former had a lower denaturation temperature by about 0.5 degrees C than the latter. The lower stability of skin collagen, however, is not due to the low levels of imino acids because the contents of Pro and Hyp were almost constant in both collagens. On the other hand, some cDNAs coding for the N-terminal and/or a part of triple-helical domains of proalpha(I) chains were cloned from the cDNA library of rainbow trout fibroblasts. These cDNAs together with the previously cloned collagen cDNAs gave information about the complete primary structure of type I procollagen. The main triple-helical domain of each proalpha(I) chain had 338 uninterrupted Gly-X-Y triplets consisting of 1014 amino acids and was unique in its high content of Gly-Gly doublets. In particular, the bonyfish-specific alpha(I) chain, proalpha3(I) was characterized by the small number of Gly-Pro-Pro triplets, 19, and the large number of Gly-Gly doublets, 38, in the triple-helical domain, compared to 23 and 22, respectively, for proalpha1(I). The small number of Gly-Pro-Pro and the large number of Gly-Gly in proalpha3(I) was assumed to partially loosen the triple-helical structure of skin collagen, leading to the lower stability of skin collagen mentioned above. Finally, phylogenetic analyses revealed that proalpha3(I) had diverged from proalpha1(I). This study is the first report of the complete primary structure of fish type I procollagen.     

Polyamines induce aggregation of LHC II and quenching of fluorescence in vitro

Dissipation of excess excitation energy within the light-harvesting complex of Photosystem II (LHC II) is a main process in plants, which is measured as the non-photochemical quenching of chlorophyll fluorescence or qE. We showed in previous works that polyamines stimulate qE in higher plants in vivo and in eukaryotic algae in vitro. In the present contribution we have tested whether polyamines can stimulate quenching in trimeric LHC II and monomeric light-harvesting complex b proteins from higher plants. The tetramine spermine was the most potent quencher and induced aggregation of LHC II trimers, due to its highly cationic character. Two transients are evident at 100μM and 350μM for the fluorescence and absorbance signals of LHC II respectively. On the basis of observations within this work, some links between polyamines and the activation of qE in vivo is discussed.     

Single-molecule electron tunneling spectroscopy of the higher plant light-harvesting complex LHC II

Electronic spectroscopy of a single biological molecule is demonstrated with approximately 4 A spatial resolution. The light-harvesting complex II (LHC II), in the ground and photo-excited states, was studied using scanning tunneling microscopy and spectroscopy of intact Photosystem II complexes. Analysis of the spectra indicates that the main mechanisms of tunneling between the STM tip and the surface involve delocalized electronic states of the LHC II and local vibronic states associated with C=C, C=O, C-H, N-H, and O-H groups near the LHC II surface. Conduction within the bulk LHC II is then due to ohmic and hopping conduction as well as tunneling between amino acid residues. Light activation of LHC II occurs via a photoconductive rather than a photovoltaic mechanism. There is a dramatic light-induced increase in the electronic density of states indicating a light-induced enhancement of energy and electron delocalization which is important for the efficient and rapid transfer of excitation energy from LHC II to the Photosystem II reaction center.