Development of rat soleus endplate membrane following denervation at birth

Rat soleus endplates develop some of their characteristic features before birth and others after birth. Specializations appearing before birth include a localized cluster of acetylcholine receptors (AChRs), an accumulation of acetylcholinesterase (AChE) in the synaptic basal lamina, and a cluster of nuclei near the endplate membrane. In contrast, postsynaptic membrane folds are elaborated during the first three weeks after birth. We denervated soleus muscles on postnatal day 1, before folds had appeared, and followed the subsequent development of endplate regions with light and electron microscopy. We found that the denervated endplates initiated fold formation on schedule and maintained their accumulations of AChRs, AChE, and endplate nuclei. However, the endplates stopped fold formation prematurely and eventually lost their rudimentary folds. At about the same time, the junctional AChR clusters were joined by ectopic patches of AChRs. The former endplate regions also became unusually elongated, possibly as a consequence of the lack of membrane folds. Apparently, endplate membranes have only a limited capacity for further development in the absence of both the nerve and muscle activity.     

Three-dimensional architecture of grana and stroma thylakoids of higher plants as determined by electron tomography

We have investigated the three-dimensional (3D) architecture of the thylakoid membranes of Arabidopsis (Arabidopsis thaliana), tobacco (Nicotiana tabacum), and spinach (Spinacia oleracea) with a resolution of approximately 7 nm by electron tomography of high-pressure-frozen/freeze-substituted intact chloroplasts. Higher-plant thylakoids are differentiated into two interconnected and functionally distinct domains, the photosystem II/light-harvesting complex II-enriched stacked grana thylakoids and the photosystem I/ATP synthase-enriched, nonstacked stroma thylakoids. The grana thylakoids are organized in the form of cylindrical stacks and are connected to the stroma thylakoids via tubular junctions. Our data confirm that the stroma thylakoids are wound around the grana stacks in the form of multiple, right-handed helices at an angle of 20° to 25° as postulated by a helical thylakoid model. The junctional connections between the grana and stroma thylakoids all have a slit-like architecture, but their size varies tremendously from approximately 15 × 30 nm to approximately 15 × 435 nm, which is approximately 5 times larger than seen in chemically fixed thylakoids. The variable slit length results in less periodicity in grana/stroma thylakoid organization than proposed in the original helical model. The stroma thylakoids also exhibit considerable architectural variability, which is dependent, in part, on the number and the orientation of adjacent grana stacks to which they are connected. Whereas some stroma thylakoids form solid, sheet-like bridges between adjacent grana, others exhibit a branching geometry with small, more tubular sheet domains also connecting adjacent, parallel stroma thylakoids. We postulate that the tremendous variability in size of the junctional slits may reflect a novel, active role of junctional slits in the regulation of photosynthetic function. In particular, by controlling the size of junctional slits, plants could regulate the flow of ions and membrane molecules between grana and stroma thylakoid membrane domains.     

The regeneration of neuromuscular junctions during spontaneous re-innervation of the rat diaphragm

Summary Electron microscopic observations have been made on the regeneration of neuromuscular junctions during spontaneous re-innervation of the rat diaphragm, following unilateral transsection of the phrenic nerve. 3 and 4 weeks after denervation motor end plates displayed the pattern of almost complete degeneration, i.e. persisting subneural foldings, deprived of neural contact and covered with collagen fibrils and fibrocytes. From observations at 5, 10 and 24 weeks after denervation the following sequence of events could be established: a few small axon terminals, accompanied by Schwann cells, became apposed to subneural folds, while most foldings were covered initially by Schwann cells or still by collagen fibrils. Gradually an increasing number of subneural folds came into contact with axon terminals. At 24 weeks all junctions displayed the pattern of a mature motor end plate. In the majority of regenerating neuromuscular junctions single dense-cored vesicles of approximately 900–1200 Å were present in axon terminals.It is concluded that under the present conditions restoration of neuromuscular transmission is accomplished by a re-innervation of the preserved subneural apparatuses of former junctions by regenerating axons. The significance of the occurrence of dense-cored vesicles in regenerating motor end plates is discussed.This work was supported by the Deutsche Forschungsgemeinschaft and the Stiftung Volkswagenwerk.     

The three-dimensional structure of motor endplates in different fiber types of rat intercostal muscle

Summary The three-dimensional organization of the motor end plates in the red, white and intermediate striated muscle fibers of the rat intercostal muscle was observed under a field-emission type scanning electron microscope after removal of connective tissue components by HCl hydrolysis.The motor endplate of the white fiber had terminal branches (or axon terminals), which were large, long and thin, and small but numerous nerve swellings (or terminal boutons). The motor endplate of the red fiber had terminal branches, which were small, short and thick, and had large but fewer nerve swellings. The motor endplate of the intermediate fiber was intermediate in size and structure between these two. In detached nerve-ending preparations, primary synaptic grooves with slit-like openings of the junctional folds appeared on the surface of the muscle fibers. The primary synaptic grooves were more developed in the white fiber than in the red fiber, and they were intermediate in the intermediate fiber. The numerical ratio of slit-like openings was 11.83.5 in the red, intermediate and white fiber, respectively.The Schwann cells and their processes were observed on the surface of the motor endplate, with the processes covering the upper orifices of the primary synaptic grooves and sealing the terminal branches. The number of Schwann cells was usually three in the white fiber, two in the intermediate fiber and one in the red fiber.     

SUBMICROSCOPIC ORGANIZATION OF THE POSTSYNAPTIC MEMBRANE IN THE MYONEURAL JUNCTION : A Polarization Optical Study

Cross-striated muscles of frogs and rats were fixed in 3.3 per cent lead nitrate solution. Frozen sections 30 micra thick were mounted in different media and observed by polarization microscopy. The subneural apparatus of myoneural junctions exhibits a strong birefringence in these sections. Birefringence is exerted by a highly organized lipoprotein framework (postsynaptic material) which builds up the "organites" (junctional folds) of the postsynaptic membrane. Synaptic cholinesterase is closely associated with this material. Freezing and/or formalin fixation results in a destruction of the molecular organization of the postsynaptic material, but does not influence the synaptic enzyme activity. It is hypothesized from this study that the junctional folds (postsynaptic "organites") consist of regularly arranged, sheet-like lamellar micellae in the frog and of less regular, mainly radially arranged submicroscopic units in the rat. The micellar organization as revealed by polarization analysis is in good agreement with the electron microscopic findings reported in the literature. Intramicellar protein molecules of the resting postsynaptic membrane are arranged longitudinally, lipids transversely. Supramaximal stimulation or treatment with acetylcholine + eserine results in a disorganization of proteins and a rearrangement of lipids. Denervation results in a rearrangement of lipids without any significant alterations of proteins. All these functional stresses influence only the molecular and not the micellar structure of the membrane. The function of the organized lipoprotein framework as an acetylcholine receptor is suggested.     

THE ULTRASTRUCTURE OF A REPTILIAN MYONEURAL JUNCTION

Myoneural junctions in Anolis are characterized by the formation of troughs in the surface of the muscle fibers in which small branches of the terminal axon lie. The muscle surface membrane lining the troughs is thrown into complex branching and anastomosing folds, which compose the subneural apparatus of Couteaux. A compound membrane 500 to 700 A thick separates axoplasm from sarcoplasm at the endings. This consists of five distinct layers and is described in detail. A thin layer of cytoplasm (probably Schwann) separates terminal axoplasm from extracellular space at the surfaces of the junctional troughs. Terminal axoplasm lacks axoplasmic filaments and contains numerous vesicular or tubular appearing structures about 300 to 500 A in diameter. Both terminal axoplasm and sarcoplasm contain numerous mitochondria.     

The development of glyoxysomes in maize scutellum: changes in morphology and enzyme compartmentation

Changes in the ultrastructural aspect of the glyoxysome fraction obtained from maize scutella by density gradient centrifugation were followed during the first 6 days of germination. During the first 2 days the fraction consists of very electron-dense bodies about 0.3 to 0.5 micron in size while at the 4th day it is formed by larger and less dense membrane-bound particles. Some intermediate form between the two types of organelles can be seen at the 3rd day. Between the 4th and the 6th days of germination the glyoxysomes are destroyed, and their enzymes are released into the cytosol. At the peak of their development (4th day) the glyoxysomes contain 75 to 80% of the total isocitratase and 65% of the total malate synthetase of the scutellum. These values drop to very low levels during the next 2 days. Catalase bound to glyoxysomes amounts to 30 to 35% of the total activity present in the scutellum at the 1st day of germination: this value decreases steadily during the following days.     

Fasciola gigantica: surface topography of the adult tegument

Adult Fasciola gigantica are leaf-shaped with tapered anterior and posterior ends and measure about 35 mm in length and 15 mm in width across the mid section. Under the scanning electron microscope its surface appears rough due to the presence of numerous spines and surface foldings. Both oral and ventral suckers have thick rims covered with transverse folds and appear spineless. On the anterior part of the ventral surface of the body, the spines are small and closely-spaced. Each spine has a serrated edge with 16 to 20 sharp points, and measures about 20 microm in width and 30 microm in height. In the mid-region the spines increase in size (up to 54 microm in width and 58 microm in height) and number, especially towards the lateral aspect of the body. Towards the posterior end the spines progressively decrease in both size and number. The tegumental surface between the spines appears highly corrugated with transverse folds alternating with grooves. At higher magnifications the surface of each fold is further increased with a meshwork of small ridges separated by variable-sized pits or slits. There are three types of sensory papillae on the surface. Types 1 and 2 are bulbous, measuring 4-6 microm in diameter at the base with nipple-like tips, and the type 2 also have short cilia. Type 3 papillae are also bulbous and of similar size but with a smooth surface. These sensory papillae usually occur in clusters, each having between 2 and 15 units depending on the region of the body. Clusters of papillae on the lateral aspect (usually types 1 and 2) and around the suckers (type 3) tend to be more numerous and larger in size. The dorsal side of the body exhibits similar surface features, but the spines and papillae appear less numerous and are smaller. Corrugation and invaginations of the surface are also less extensive than on the ventral side of the body.     

Acetylcholinesterase in the fast extraocular muscle of the mouse by light and electron microscope autoradiography

The distribution of acetylcholinesterase (ACHe) in the twitch fibers of the extraocular muscles of the mouse was examined by light and electron microscope autoradiography after labeling with radioactive diisopropyl fluorophosphate (DFP) with, and without, 2-pyridine aldoxime methiodide (2-PAM) reactivation. The values obtained were compared with those previously reported for the diaphragm and sternomastoid muscles. The extraocular muscles were studied because they differ from the other two muscles in that they are among the fastest of the mammalian muscles, yet their endplates have sparse junctional folds. They could thus provide information on the extent to which ACHe concentration is an invariant feature of endplate morphology and what, if any aspects may be related to their fast speed of response. We found, using light microscope autoradiography, that in the twitch fibers of the extraocular muscle, there is n average of 6.4 +/- 2.1 X 10(7) DFP- binding sites per endplate, of which 29% (1.8 X 10(7)) are reactivated by 2-PAM and are thus AChe. The morphology of the extraocular endplates allowed us to conclude, on statistical grounds, that the AChe site are probably localized not only along the surface area of the postjunctional membrane (PJM) but also along the surface of the presynaptic axonal membrane. Based on this localization, we calculate 7,800 DFP sites and 2,500 2-PAM-reactivated sites/micron 2 of surface area of pre-and postjunctional membrane. This stacking density of DFP- binding sites per surface area of membrane ( probably in the overlying sheets of basal lamina) is very similar to that in the diaphragm and sternomastoid muscles.     

The role of extracellular material in chick neurulation. II. Surface morphology of neuroepithelial cells during neural fold fusion

Changes in cell surface morphology of the neuroepithelium during fusion of neural folds in the chick were studied. As the folds were about to meet, a thick extracellular coat material (ECM) appeared between the two leading edges. Cell membranes forming the fusion area were relatively smooth and heavily coated with ECM. By contrast, the apical surface of most cells lining the wall of the neural tube was folded with much less ECM. During the contact of neural folds, ECM was displaced from the space between the two leading edges, leaving a thin, closely adherent "typical" cell surface coat. Trypsin and concanavalin A inhibited proper alignment and fusion of apposing neural folds by modifying the surface of developing neuroepithelium. Results of this study support a hypothesis that ECM may serve temporarily as an adhesive to bind together the leading edges of neural folds until establishment of more intimate contacts (junctional complexes).     

Effect of castration and testosterone administration on the neuromuscular junction in the levator ani muscle of the rat

Summary The ultrastructure of the neuromuscular junction (n.m.j.) of the androgen-sensitive levator ani muscle was studied in normal adult male rats, in 8-month-old rats castrated at the age of one month and in castrated rats treated with testosterone propionate (TP). Castration does not result in significant changes of the n.m.j. The density of synaptic vesicles and the postsynaptic junctional folds remain practically normal in spite of marked atrophy of the muscle. TP administration for 7 days results in marked changes in preand postsynaptic structures. There is slow progressive depletion of synaptic vesicles, appearance of cisternae and coated vesicles in axon terminals, and coalescence of coated vesicles with the plasma membrane. Coated vesicles are also found inside Schwann cells and among junctional folds. Dense core vesicles appear both in the axon terminals and in the postsynaptic area. Collateral sprouting of terminal axons with the formation of new immature junctions is observed. After 35 days of TP administration depletion of synaptic vesicles continues. Glycogen -particles, mostly freely dispersed, occasionally seen in axon terminals 7 days after TP administration, subsequently increase in number. In the endplate zone of the muscle fibre increased protein synthesis is indicated by a rapid increase in ribosomes and irregularly located myofilaments and myofibrils. The appearance of n.m.j. after testosterone administration resembles that described after nerve stimulation; the degree of change is however less pronounced.The authors wish to acknowledge the skillful technical assistance of Mrs. L. Vedralová     

Attachment of acetylcholinesterase to structures of the motor endplate

Summary The kinetics of AChE solubilization from intact motor endplates of mouse diaphragm, by collagenase, papain and hyaluronidase, was studied in parallel with the ultrastructural localization of AChE in treated neuromuscular junctions. Hyaluronidase did not solubilize more AChE from isolated motor endplate regions than Ringer's solution itself. Residual AChE activity could be demonstrated histochemically in motor endplates even after the plateau of solubilization by collagenase or papain was reached. Less than 35% of junctional AChE is left after collagenase, and less than 20% after papain treatment, as estimated by the percentage of AChE activity left in the isolated endplate region of the diaphragm after protease treatment. Cytochemically, both proteases had a similar effect on postsynaptic AChE. Residual AChE activity was distributed randomly, adhering to the sarcolemma of junctional clefts. Presynaptic AChE localized in the gap between axon terminal and Schwann cell appears to be resistant to collagenase but not to papain treatment. The mode of AChE attachment or the composition of the intercellular material in this gap may differ from that of the primary and secondary clefts.     

A quantitative study of intramembrane changes during cell junctional breakdown in the dystrophic rat retinal pigment epithelium

Previous electron microscope freeze-fracture and tracer studies have revealed that intercellular junctions in the retinal pigment epithelium (RPE) of Royal College of Surgeons (RCS) rats with inherited retinal dystrophy [5] break down between three and six postnatal weeks [6, 7]. In this study quantitative computer techniques were used to analyze the freeze-fracture changes in the dystrophic RPE. The following parameters were measured: length of tight junctional strands/micron2; number of tight junctional strand anastomoses/micron2; number of gap junctional aggregates/micron2; area of gap junctional aggregates/micron2; and density of background intramembrane particles/micron2. At three postnatal weeks, the dystrophic junctional complex membrane is similar to normal, but at 10 weeks and later there are dramatic decreases in tight junctional strand length/micron2 and number of anastomoses/micron2, as well as in the number/micron2 and area of gap junctions/micron2, while the density of background particles/micron2 is dramatically increased. Correlational analysis revealed that changes in gap and tight junctions were significantly related to each other and to the increase in background particle density. The diameter of background particles within the normal and post-breakdown dystrophic junctions was measured in order to see whether the dispersal of gap and tight junctional particles (8-10 nm) into the surrounding membrane contributes to the increased particle density. These measures showed that background particles in all size ranges were more numerous in the dystrophic RPE, but that the largest increase was in the smallest diameter particles (6-7 nm). Thus, while gap and tight junctional sized particles contribute to the increase, particles from other sources may also be involved. Particle density of apical and basal membranes in the normal and in the 10 week and older dystrophic RPE was analyzed to study the effects of tight junctional breakdown on the distribution of intramembrane particles. These measures showed that particle density was greater basally than apically in the normal RPE and that particle density in both membranes decreased slightly in the dystrophic RPE, but that their ratio remained unchanged. It has been shown previously that even a single intact tight junctional strand is sufficient to maintain differences in particle density between apical and basal surfaces [14, 15] and in the majority of abnormal dystrophic junctional complexes at least one tight junctional strand remains intact.(ABSTRACT TRUNCATED AT 400 WORDS)     

René Couteaux (1909-1999) and the morphological identification of synapses

During a historical research, we realized that René Couteaux (1909-1999) was the first histologist who stained the postsynaptic structure of the neuromuscular junction. By means of Janus Green B dye, he revealed the membranous 'subneural apparatus' related to the 'synaptic gutter'. Hence, he justified the use of the physiological term 'synapse' in histology. A few years later, Couteaux localized acetylcholinesterase activity on this subneural apparatus with a histo-enzymatic method. The histochemical staining confirmed his histological observations that the subneural apparatus of the muscle cells was distinct from the nerve terminal. Thus Couteaux not only supported Cajal's neuron theory, but also gave decisive morphological basis to the concept of the synapse, thought to be up to that time a physiological entity. These observations were performed several years before the first electron microscopic data obtained in the U.S.A. When the electron microscopy became available in Europe, Couteaux studied the ultrastructural details of the myoneural synapse. He found evidence for the presynaptic 'active zone' as a restricted zone of the thickened presynaptic membrane flanked on both sides with synaptic vesicles, some of which were observed to be opening into the synaptic cleft by exocytosis. Furthermore, the synaptic vesicles were shown to be displayed in two rows along the linearly prolonged active zone which is situated just above the 'trench-like' junctional folds of the muscle membrane. The discontinuity of the synaptic structure was confirmed by the three-dimensional observation of the intraneuronal network of neurofibrils with the first prototype of high-voltage electron microscope.     

STRUCTURE OF MEMBRANE HOLES IN OSMOTIC AND SAPONIN HEMOLYSIS

Serial section electron microscopy of hemolysing erythrocytes (fixed at 12 s after the onset of osmotic hemolysis) revealed long slits and holes in the membrane, extending to around 1 µm in length. Many but not all of the slits and holes (about 100–1000 Å wide) were confluent with one another. Ferritin and colloidal gold (added after fixation) only permeated those cells containing membrane defects. No such large holes or slits were seen in saponin-treated erythrocytes, and the membrane was highly invaginated, giving the ghost a scalloped outline. Freeze-etch electron microscopy of saponin-treated membranes revealed 40–50 Å-wide pits in the extracellular surface of the membrane. If these pits represent regions from which cholesterol was extracted, then cholesterol is uniformly distributed over the entire erythrocyte membrane.     

Leukocyte, lymphocyte and platelet response to dynamic exercise. Duration or intensity effect?

The influence of work intensity and duration on the white blood cell (WBC), lymphocyte (L) and platelet (P) count response to exercise was studied in 16 trained subjects (22 +/- 5.4 years, means +/- SD). They performed three cyclo-ergospirometric protocols: A) 10 min at 150 W followed by a progressive test (30 W/3 min) till exhaustion; B) constant maximal work (VO2max); C) a 45 min Square-Wave Endurance Exercise Test (SWEET), (n = 5). Arterial blood samples were taken: at rest, submaximal and maximal exercise in A; maximal exercise in B; 15th, 30th and 45th min in the SWEET. Lactate, [H+], PaCO2, PaO2, [Hct], Hb, cortisol, ACTH, total platelet volume (TPV), total blood red cell (RBC), WBC, L and P were measured. At 150 W, WBC, L, P, and TPV increased. VO2max did not differ between A and B, but a difference was found in total exercise time (A = 25 +/- 3 min; B = 7 +/- 2 min, p less than 0.001). In A, at VO2max, the increase was very small for Hct, [Hb], and RBC (10%), in contrast with large changes for WBC (+93%), L (+137%), P (+32%), TPV (+35%), [H+] (+39%), lactate (+715%), and ACTH (+95%). At VO2max there were no differences in these variables between A and B. During the SWEET: WBC, L, P, TPV and ACTH increased at the 15th min as much as in VO2max, but no difference was observed between the 15th, 30th and 45th min, except for ACTH which continued to rise; the lactate increase during the SWEET was about half (+341%) the value observed at VO2max, and [H+] did not vary with respect to values at rest.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural development of myoneural junctions in the human embryo

Summary The structure of myoneural junctions in the tibialis anterior and intercostal muscles was studied after histochemical reaction for myoneural acetylcholinesterase (E.C. 3.1.1.7) in human embryos.Myoneural junctions of a primitive form were first seen in the intercostal muscle at the age of 8.6 weeks (crown-rump length of 3.2 cm), and in the tibialis anterior muscle at the age of 10 weeks (4.3 cm). The postsynaptic membrane was devoid of any junctional folds typical of adult synapses up to the age of about 19 weeks. At first small, the junctional folds gradually became deeper and more prominent during the following weeks, and some ramification of the previously coherent postsynaptic area took place. Myoneural morphogenesis was not completed at birth, although well developed postsynaptic Moldings were present.     

Structural alterations at the neuromuscular junctions of matrix metalloproteinase 3 null mutant mice

Matrix metalloproteinases are important regulators of extracellular matrix molecules and cell-cell signaling. Antibodies to matrix metalloproteinase 3 (MMP3) recognize molecules at the frog neuromuscular junction, and MMP3 can remove agrin from synaptic basal lamina (VanSaun & Werle, 2000). To gain insight into the possible roles of MMP3 at the neuromuscular junction, detailed observations were made on the structure and function of the neuromuscular junctions in MMP3 null mutant mice. Striking differences were found in the appearance of the postsynaptic apparatus of MMP3 null mutant mice. Endplates had an increased volume of AChR stained regions within the endplate structure, leaving only small regions devoid of AChRs. Individual postsynaptic gutters were wider, containing prominent lines that represent the AChRs concentrated at the tops of the junctional folds. Electron microscopy revealed a dramatic increase in the number and size of the junctional folds, in addition to ectopically located junctional folds. Electrophysiological recordings revealed no change in quantal content or MEPP frequency, but there was an increase in MEPP rise time in a subset of endplates. No differences were observed in the rate or extent of developmental synapse elimination. In vitro cleavage experiments revealed that MMP3 directly cleaves agrin. Increased agrin immunofluorescence was observed at the neuromuscular junctions of MMP3 null mutant mice. These results provide strong evidence that MMP3 is involved in the control of synaptic structure at the neuromuscular junction and they support the hypothesis that MMP3 is involved in the regulation of agrin at the neuromuscular junction.     

Gap junctions in the heart of the adult Protopterus aethiopicus

In thin sections and in freeze-fracture replicas small and sparse gap junctions appear to be developed on the longitudinal plasma membrane of Protopterus cardiac cells near a macula or fascia adhaerens. By thin-section electron microscopy, they had septalaminar profiles with a length between 0.042 and 0.260 micron. In freeze-fracture images they appear on the P-fracture face as maculate particle aggregations with complementary pits on the E-fracture face. Particles with a central intercellular channel could be observed. The average center-to-center distance between neighbouring particles or pits is 10.05 +/- 1.87 nm (N = 2429). The diameter of the junctional maculae in replicas lies between 0.037 and 0.229 nm. The particle packing density increases in larger maculate aggregations, while particle-free areas emerge which could be related to the degradation or reformation of gap junctions Atypical configurations of gap junctions observed in the myocardium of lower vertebrates are rarely encountered in this primitive vertebrate.     

Regulation of turnover and number of acetylcholine receptors at neuromuscular junctions

The number and metabolic stability of acetylcholine receptors (AChRs) at neuromuscular junctions of rat tibialis anterior (TA) and soleus (SOL) muscles were examined after denervation, paralysis by continuous application of tetrodotoxin to the nerve, or denervation and direct stimulation of the muscle through implanted electrodes. After 18 days of denervation AChR half-life declined from about 10 days to 2.3 days (TA) or 3.6 days (SOL) and after 18 days of nerve conduction block to 3.1 days (TA). In contrast, the total number of AChRs per endplate was unaffected by these treatments. Denervation for 33 days had no further effect on AChR half-life but reduced the total number of AChRs to about 54% (SOL) or 38% (TA) of normal. Direct stimulation of the 33-day denervated SOL from day 18 restored normal AChR stability and counteracted muscle atrophy but had no effect on the decline in AChR number. The results indicate that motoneurons control the stability of junctional AChRs through evoked muscle activity and the number of junctional AChRs through trophic factors.