It’s possible that I shall make an ass of myself. But in that case one can always get out of it with a little dialectic. I have, of course, so worded my proposition as to be right either way (K.Marx, Letter to F.Engels on the Indian Mutiny)
A team of researchers from the Universitat Politècnica de València (UPV), belonging to the Instituto Universitario de Conservación y Mejora de la Agrodiversidad Valenciana (COMAV), and the Universidad Técnica Particular de Loja (Ecuador) has evaluated the effects of climatic conditions on local and commercial varieties of beans (Phaseolus vulgaris), garrofón (P. lunatus) and green beans (Vigna unguiculata) traditionally sown under cold or hot conditions.
By subjecting these varieties to different temperatures, the researchers have evaluated the impact of the effects of climate change on vital parameters of these varieties, such as their morphology, reproduction, production, and phenology. Thus, they have detected some very sensitive types to variations in their conditions of origin. These others perform better with the increase in temperature, and others are highly resilient to any change.
The study is led by the COMAV researcher at the UPV, Mario X. Ruiz, who stresses that "during the research, we have identified the most fragile varieties in the face of the effects of climate change, which is why it is a priority to preserve them".
Thus, this study shows that some bean varieties perform better at higher temperatures, making them an excellent alternative to replace less productive types due to climate change. One local variety even proved to be more resistant than the commercial variety used as a control. Green beans (bachoqueta), whose origin is African, resisted relatively well to increases in temperature, as did locust beans.
The research also highlights the importance of considering the environmental and ecological background from which the varieties under study originate. In short, the results obtained have an immediate application in the conservation of agrobiodiversity by revealing which varieties are most sensitive to the effects of climate change and which should be conserved as a priority.
It also highlights the importance of promoting the resilience of food sovereignty in the face of environmental challenges, as identifying those varieties best adapted to the new conditions will allow crops to be implemented locally.
In plant breeding, the identification of traits most affected by the environment will enable crop improvement, as this research not only helps to boost adaptation to climate change but also to other disasters such as the COVID-19 pandemic, which has led to a shortage in the supply of commercial seeds in developing communities.
In this sense, Mario X. Ruiz stresses that "the pandemic has produced a shortage of commercial seeds in developing communities. Thanks to our research, we can find the best alternatives to maintain production locally".
The results of this study have been published in the journal Scientific Reports.
Researchers have used a widespread species of blue-green algae to power a microprocessor continuously for a year - and counting - using nothing but ambient light and water. Their system has potential as a reliable and renewable way to power small devices.
The system, comparable in size to an AA battery, contains a type of non-toxic algae called Synechocystis that naturally harvests energy from the sun through photosynthesis. The tiny electrical current this generates then interacts with an aluminium electrode and is used to power a microprocessor.
The system is made of common, inexpensive and largely recyclable materials. This means it could easily be replicated hundreds of thousands of times to power large numbers of small devices as part of the Internet of Things. The researchers say it is likely to be most useful in off-grid situations or remote locations, where small amounts of power can be very beneficial.
“The growing Internet of Things needs an increasing amount of power, and we think this will have to come from systems that can generate energy, rather than simply store it like batteries,” said Professor Christopher Howe in the University of Cambridge’s Department of Biochemistry, joint senior author of the paper.
He added: “Our photosynthetic device doesn’t run down the way a battery does because it’s continually using light as the energy source.”
In the experiment, the device was used to power an Arm Cortex M0+, which is a microprocessor used widely in Internet of Things devices. It operated in a domestic environment and semi-outdoor conditions under natural light and associated temperature fluctuations, and after six months of continuous power production the results were submitted for publication.
The study is published today in the journal Energy & Environmental Science.
“We were impressed by how consistently the system worked over a long period of time – we thought it might stop after a few weeks but it just kept going,” said Dr Paolo Bombelli in the University of Cambridge’s Department of Biochemistry, first author of the paper.
The algae does not need feeding, because it creates its own food as it photosynthesises. And despite the fact that photosynthesis requires light, the device can even continue producing power during periods of darkness. The researchers think this is because the algae processes some of its food when there’s no light, and this continues to generate an electrical current.
The Internet of Things is a vast and growing network of electronic devices - each using only a small amount of power - that collect and share real-time data via the internet. Using low-cost computer chips and wireless networks, many billions of devices are part of this network - from smartwatches to temperature sensors in power stations. This figure is expected to grow to one trillion devices by 2035, requiring a vast number of portable energy sources.
The researchers say that powering trillions of Internet of Things devices using lithium-ion batteries would be impractical: it would need three times more lithium than is produced across the world annually. And traditional photovoltaic devices are made using hazardous materials that have adverse environmental effects.
The work was a collaboration between the University of Cambridge and Arm, a company leading the design of microprocessors. Arm Research developed the ultra-efficient Arm Cortex M0+ testchip, built the board, and set up the data-collection cloud interface presented in the experiments.
A new study from North Carolina State University shows the behavioral mechanism behind a sweet cockroach mating ritual that takes a bitter turn, resulting in rejected males.
Male German cockroaches (Blattella germanica) offer females a pre-mating “gift” of body secretions that combines sugars and fats – think of the roach version of chocolate – in order to attract and hold female attention long enough to start copulation.
“This is common mating behavior in insects and some other animals: males present females a tasty or valuable gift – it’s like Valentine’s Day, but every day,” said Coby Schal, Blanton J. Whitmire Distinguished Professor of Entomology at NC State and co-corresponding author of the paper.
The study shows, however, that females averse to the simple sugar glucose get an unpleasant surprise when they mix their saliva with the male secretions – saliva degrades the sweet treat of complex sugars to glucose, which becomes a bitter pill that ends the courtship ritual, with the female scurrying away without mating.
“We’re seeing glucose-averse female German cockroaches turning down this nuptial gift – and the chance to mate – and wanted to understand more about the mechanism behind it,” said Ayako Wada-Katsumata, principal research scholar at NC State and co-corresponding author of the paper.
Generally, cockroaches love sugar. But some have developed an aversion to glucose; Wada-Katsumata in 2013 published a paper that showed the neural mechanism behind this aversion in German cockroaches, a behavior that perhaps has become more pronounced due to the presence of the simple sugar in roach baits placed inside homes. In a 2021 paper, Wada-Katsumata and Schal showed that cockroach saliva converts complex sugars into glucose.
“Male cockroach secretions have different types of sugars – in this case maltose and maltotriose, which are usually preferred by females – as well as some fats,” Wada-Katsumata said. Maltose is relatively easy to convert to glucose, while maltotriose is more complex and takes a bit longer to break down into glucose, she said.
“Cockroach saliva has a class of chemicals that breaks down sugars,” Schal said. “As females feed on their gift, maltose is rapidly converted to glucose, and glucose-averse females sense a bitter taste and stop feeding, which also ends the mating opportunity.”
The cockroach mating process is interesting but likely unfamiliar to bipeds. Males approach females, raise their wings, and release chemicals via the tergal gland on their backs. Females attracted to the secretion will climb onto the male’s back and feed on the secretion. While she feeds, the male will telescope his abdomen under the female, grab her with an elongated hooked penis and move into position for mating. This courtship process takes only seconds; it is here that the rapid chemical conversion of complex sugars to simple sugars in saliva could kill the mood for glucose-averse females. If successful, though, roaches engage in a back-to-back, up to 90-minute-long mating session, with the male using a second penis to transfer a sperm package to the female.
In the study, the researchers performed various experiments to ascertain how glucose aversion affects cockroach courtship. They found that glucose-averse females more frequently interrupted feeding due to their aversion, especially when feeding from a wild-type male – one that was not averse to glucose. Glucose-averse males often had higher levels of maltotriose in their secretions, which converted less easily to glucose and therefore gave those males extra time to begin mating.
The researchers also changed the quality of the male secretion, substituting fructose for the glucose and maltose secretions. Glucose-averse females enjoyed fructose and fed on it longer, resulting in more successful mating sessions.
“This study is a direct way to show that the quality of secretion affects female behavior and mating success,” Schal said. “There is a tradeoff between sexual selection and natural selection. Think of deer as an example. Male deer have horns, not for natural selection – horns actually put males in danger from predators and hunters – but for sexual selection to appeal to females and serve as useful weapons in competition with other males. Similarly, the cockroach’s tergal gland evolved for attracting females in the context of sexual selection.”
“Wild-type females accept the sugary secretions. Glucose-averse females don’t accept the wild-type secretions because they easily convert to glucose. Males can change the composition of secretions – perhaps producing more maltotriose which takes longer to convert to glucose – or try to mate faster. In short, the glucose aversion trait evolved under natural selection, but under sexual selection it is causing the male to modify his sexual secretion and behavior,” Wada-Katsumata said.
The 2013 study informed bait manufacturers not to use glucose in baits. The 2021 studies expand this recommendation to all sugars that contain glucose. Baits made with glucose, sucrose, maltose and other sugars will be ignored by glucose-averse cockroaches. As more cockroaches with glucose aversion survive, that trait will be passed down in greater numbers.
“We are constantly in an evolutionary battle with cockroaches,” Schal said. “Evolution can be sped up tremendously in the urban, human environment because the selection force imposed on insects, especially inside homes, is so intense.”
The study appears in Nature Communications Biology. Postdoctoral scholar Eduardo Hatano, Ph.D. student Samantha McPherson and Jules Silverman, Charles G. Wright Distinguished Emeritus Professor of Entomology, co-authored the paper. The research was supported by the National Science Foundation under grant IOS-1557864, the U.S. Department of Housing and Urban Development Healthy Homes program (NCHHU0053-19), and the Blanton J. Whitmire Endowment at NC State.
- kulikowski -
Note to editors: An abstract of the paper follows.
“Rapid evolution of an adaptive taste polymorphism disrupts courtship behavior” Authors: Ayako Wada-Katsumata, Eduardo Hatano, Samantha McPherson, Jules Silverman and Coby Schal, North Carolina State University
Published: May 12, 2022 in Nature Communications Biology
DOI: 10.1038/s42003-022-03415-8
Abstract: The evolution of adaptive behavior often requires changes in sensory systems. However, rapid adaptive changes in sensory traits can adversely affect other fitness-related behaviors. In the German cockroach, a gustatory polymorphism, ‘glucose-aversion (GA)’, supports greater survivorship under selection with glucose-containing insecticide baits and promotes the evolution of behavioral resistance. Yet, sugars are prominent components of the male’s nuptial gift and play an essential role in courtship. Behavioral and chemical analyses revealed that the saliva of GA females rapidly degrades nuptial gift sugars into glucose, and the inversion of a tasty nuptial gift to an aversive stimulus often causes GA females to reject courting males. Thus, the rapid emergence of an adaptive change in the gustatory system supports foraging, but it interferes with courtship. The trade-off between natural and sexual selection under human-imposed selection can lead to directional selection on courtship behavior that favors the GA genotype.
A research conducted by the UAB with road cyclists, published in the journal PeerJ, sheds light on the importance of monitoring a training session load with the use of heart rate variability measuring tools, to favour assimilation and prevent injuries, and to compare training intensity with mood states the following morning.
To build fitness, athletes must apply stress to the body, and then through recovery, the body adapts and is able to accomodate greater stress in the next round of training. Controlling the adequate amounts of stress and recovery is essential to ameliorate the performance of athletes, as well as to prevent injuries and problems associated with overtraining.
Researchers from the Laboratory of Sport Psychology and the Sport Research Institute at the UAB have studied the effects training intensity has on road cyclists in terms of mood states and their capacity to adapt to greater training loads, assessed using heart rate variability (HRV).
The research, published in the journal PeerJ, was conducted through a six-week analysis of the answers five amateur road cyclists gave of the physical stress they endured during training. Once completed, the cyclists also responded questionnaires on how they had perceived the physical exertion of their training. The following morning they measured their HRV and recorded their mood state.
The researchers argue that a change in mood and/or HRV – measured using the HFnu (normalised high frequency band) parameter – in athletes the day after training could serve as indicator of training intensity, signalling whether the training had been adequate or too intense for the physical state of the athlete. The study observed that the more intense the training, the lower the mood on the following day, and also the lower the HRV. In contrast, high HFnu was associated with an improvement in the mood of atletes, which indicated that there is a relationship between HRV and mood states.
“The objective of the research was to explore the relation among three aspects: training, heart rate variability and mood”, explains researcher of the UAB Department of Basic Psychology Carla Alfonso. “With this study we aimed to know when an athlete must rest, because their system is saturated, and when an athlete can train, with more or less intensity, because their body is ready to assimilate the training load”.
The results obtained are a first step in “setting up a monitoring system which takes into account both internal and external training loads, in addition to mood state and heart rate variability of the athlete, with the aim of helping them adapt to their training and prevent injuries that may come with overtraining”, concludes Professor Lluís Capdevila of the UAB Department of Basic, Developmental and Educational Psychology, and co-author of the study.
The cerebral cortex is thought to be the seat of conscious processing in the brain. Rather than being inactivated, specific cells in the cortex show higher spontaneous activity during general anesthesia than when awake, and this activity is synchronized across those cortical cells. Improving our understanding of the neuronal mechanisms of general anesthesia could lead to better anesthetic drugs and improved surgical outcomes.
In a paper recently published in Neuron, researchers from the group of Professor Botond Roska at the University of Basel and the Institute of Molecular and Clinical Ophthalmology (IOB) reveal how different cell types in cortex change their activity during general anesthesia, helping to understand how unconsciousness may be induced.
You are lying on the operating table. The doctor tells you to count to 5, and places an anesthetic mask on your face. By the count of 4, you’ve lost consciousness. You will not wake up until after the surgery. What happened in your brain during this time?
One would probably assume that your brain has been silent. Especially your cortex, the brain area thought to be the seat of conscious processing. However, for close to 100 years, it has been known that some cells in the cortex are active and that cortex alternates between periods of high and low activity during general anesthesia.
Using EEG electrodes attached to the scalp is one of the few tools available to measure this activity, but electrodes don’t allow one to identify the cells underlying this activity. Therefore, the question has remained: which cells contribute to the rhythmic activity in the cortex, and how might that contribute to the loss of consciousness during general anesthesia.
On the trail of unconsciousness
Cortex is composed of different cell types, each with different functions. Different general anesthetics act on different receptors, located on different types of neurons, distributed throughout the brain. Yet, all general anesthetics lead to the loss of consciousness, and so “we were interested in finding if there is a common neuronal mechanism across different anesthetics”, says Dr. Martin Munz, one of the three first authors of the study.
In this Neuron publication, the researchers used modern genetic tools, in combination with mouse lines labeling individual cortical cell types to address this question. They found that in contrast to what had previously been suspected, only one specific cell type within cortex, layer 5 pyramidal neurons, showed an increase in activity when the animal was exposed to different anesthetics.
“Each anesthetic induces a rhythm of activity in layer 5 pyramidal neurons. Interestingly, these rhythms differed between anesthetics. Some were slower, and some were faster. However, what was common across all anesthetics was that they all induced an alignment of activity. That is, when they were active, all layer 5 pyramidal neurons were active at the same time”, says Dr. Arjun Bharioke from the same research group and also a first author of the study. “We called this ‘neuronal synchrony’”.
Layer 5 pyramidal neurons serve as a major output center for the cerebral cortex and also connect different cortical areas to each other. Thus, they communicate both between different cortical areas, as well as from the cortex to other areas of the brain. Therefore, a synchronization of activity across layer 5 pyramidal neurons restricts the information that the cortex can output.
Like a crowd at a soccer match
“It seems that instead of each neuron sending different pieces of information, during anesthesia all layer 5 pyramidal neurons send the same piece of information”, says Arjun Bharioke, “One could think of this as when people in a crowd transition from talking to each other, for example before a soccer or basketball game, to when they are cheering for their team, during the game. Before the game starts, there are many independent conversations. In contrast, during the game, all the spectators are cheering on their team. Thus, there is only one piece of information being transmitted across the crowd”.
Prior work has proposed that loss of consciousness occurs through the disconnection of cortex from the rest of the brain. The results of the IOB team suggest a mechanism by which this may occur – by the transition to lowered information output from cortex, during anesthesia.
Alexandra Brignall, the third first author and a veterinarian by trade says: “Anesthetics are very powerful, as anyone who has been in a surgery can attest to. But they are also not always easy to use. During a surgery, one has to continuously monitor the depth of the anesthetic to ensure that the patient is not too deep or too shallow. The more we know how anesthetics work and what they do in the brain, the better. Maybe this will help researchers develop new drugs to more specifically target the cells in the brain associated with unconsciousness.”
“Our findings are highly relevant for medicine, since anesthesia is one of the most frequently performed medical procedures. Understanding the neuronal mechanism of anesthesia could lead to better anesthetic drugs and improved surgical outcomes”, says Botond Roska, corresponding author and director of the IOB Molecular Research Center.
Anyone walking past a meadow on a mild summer evening is often exposed to an impressive concert. It is the grasshoppers, bush crickets and crickets that create a Mediterranean atmosphere with their chirping. The songs are usually those of males trying to attract females to mate with them. But they can also be rival songs when two males get too close to each other.
In total, there are more than 80 species of Orthoptera in Germany. "Grasshoppers are very important for many open grassland ecosystems", states zoologist Sebastian König from the Biocenter of the Julius-Maximilians-Universität (JMU) Würzburg in Bavaria, Germany: "The insects are an important food source for birds. And as herbivores, they remove up to 30 percent of the plant biomass in a meadow, thus promoting the co-occurrence of many plant species."
Climate change: How do food webs respond?
Grasshoppers and their feeding habits are a scientifically exciting topic. Generally, there is still a need for research on the feeding interactions that link plants and herbivorous insects.
Why are scientists interested in this? "It is important to understand how food webs function in order to be able to predict their stability in the context of climate change", explains König, who is a doctoral researcher at the JMU Chair of Animal Ecology and Tropical Biology headed by Professor Ingolf Steffan-Dewenter and co-supervised by Professor Jochen Krauß.
More than 3,000 grasshoppers observed
König and colleagues from Würzburg, Munich and Salzburg have published a first contribution to the understanding of Orthoptera-plant interactions in the journal Global Change Biology.
For the study, Orthoptera-plant communities were investigated in different regions - at warm sites near Karlstadt and Winterhausen in Lower Franconia as well as in the Berchtesgaden Alps, hence allowing the analysis of species communities along a climatic gradient, at altitudes ranging from 250 to 2,100 metres.
During the summers of 2019, 2020 and 2021, the team determined which grasshopper species fed on which plants on 41 grassland sites. They observed more than 3,000 individuals of 54 species and collected the faecal pellets of the animals to analyse the plant remains they contained using DNA sequencing.
Theory on food niche partially confirmed
The ecologists wanted to test the hypothesis put forward a few years ago that it should be advantageous for insects at higher altitudes to feed on a broader range of plant species. This would make sense, because in high alpine environments the choice of food plants is limited. Therefore, and because of environmental variability, it is advisable not to be too choosy there.
König's study partially confirms the hypothesis. It shows that grasshoppers eat a relatively wide range of plants in cold regions. However, this also applies to warm habitats, such as the calcareous grasslands of Lower Franconia. In temperate habitats, on the other hand, where the number of plant species is large, grasshoppers are more specialized, thus feeding on plants that are closely related. But resource composition also plays an important role for the herbivores. For example, grasshoppers with a preference for grasses dominate in meadows with a high proportion of grasses.
The researchers' conclusion: "Our results suggest that climate and plant community composition influence the dietary specialisation of herbivores. If herbivores devour many different species, this could be an adaptation and a prerequisite for being able to survive in climatically extreme habitats."
Now the microbiome of the grasshoppers is being analysed
The JMU scientists now want to gather even more facts about the food niche breadth of herbivorous insects. Next, they will analyse the microorganisms that live in the gut of the grasshoppers. In this way, possible relationships between the diet and the diversity and composition of the microorganisms will be uncovered.
Phylogenetic relatedness of food plants reveals highest insect herbivore specialization at intermediate temperatures along a broad climatic gradient.
Prepare for the next supply chain disruption
CSH scientists produce the first complete image of an entire economy. Their research indicates what’s at stake if supply chains break down – and what might be done to help
[Vienna, May 12, 2022] Researchers at the Complexity Science Hub Vienna (CSH) created a complete representation of Hungary’s economy. They mapped the entire country’s production network, including literally all of the relevant firms and all of the supply relationships with their clients and customers. With such detailed knowledge of the economy, they can compute its systemic risks.
“By viewing the economy as a network of all companies and their mutual relationships, we can now rethink economics. In particular, one can compute the risks associated with supply chain disruptions, which can be significant,” says Stefan Thurner, CSH president and co-author of the study that just appeared in Scientific Reports. “This allows us to quantify the economic systemic risk of each company within a country.”
Using a unique dataset of value-added tax (VAT) information – a general tax that, in principle, is applied to all goods and services –, the team was able to reconstruct the production processes and the supply relationships between companies to an unprecedented extent and determine how each enterprise was affected by supply chain disruptions.
“This is the first time the supply chain vulnerability of a country has been calculated at such a detailed, granular level,” states the first author of the paper, Christian Diem.
“Our approach demonstrates that the real economy cannot be seen as a collection of separate supply chains. It’s a tightly connected network that has a strongly connected component, forming the center of the network, and that contains 26 percent of all companies,” adds Diem. “Our findings indicate that only a few firms pose a substantial risk to the overall economy.”
Novel approach
The researchers propose a new methodology for calculating the economic systemic risk of companies. The method not only considers all buyer-supplier relationships between businesses, but also other factors, such as the production process of each enterprise, the supply transaction’s importance, and the firm’s value in the overall production of the economy.
The scientists reconstructed the intricate production network of Hungary based on VAT data from more than 91.000 companies provided by the Hungarian Central Bank. Their most surprising finding was the vulnerability of the Magyar economy. It could be shaken by just a handful of enterprises connected by a network of highly critical supply chain relations.
According to the study, the 32 top high-risk companies, which represent 0.035 percent of the analyzed Hungarian enterprises, display an extremely high systemic risk of about 23 percent. “This means that, in the short term, about 23 percent of the national production could be adversely affected if firms cannot adjust their supply relations by finding new suppliers and customers fast enough,” Diem explains.
In addition, almost 75 percent of the national systemic risk is concentrated on only 100 high-risk companies. “Large scale snowball or domino effects are likely caused by one of these 100 firms, while the other 99% enterprises are of marginal systemic relevance.”
Policy Implications
The researchers point out that the results have a number of policy implications.
“Using our model, government institutions could identify and monitor the weak spots of the economy – those critical companies that, in case of default, could cause system-wide damage. Once those weaknesses are known, one can consider what can and should be done to fix them and make the system more resilient. We cannot see the dangers of systemic risk without knowing the weaknesses,” explains Thurner.
“Historically, economists argued in favor of regulating the financial system more strongly than the real economy because the systemic risk in the financial system was deemed to be much higher than in the rest of the economy. However, the recent supply chain crises and our results show that systemic risk is substantial in the real economy,” adds Diem.
In addition, the paper suggests introducing larger inventory buffers for risky companies and making firms aware of their economic systemic risk in the system. “Companies might become more sustainable if they know which supply lines are reliable,” Thurner argues. With the new methodology, government institutions could take a more proactive and transparent approach to ensure that supply chains are resilient.
The pandemic effect
Business operations in countries around the world have been fundamentally altered by the Covid-19 pandemic. The pandemic has negatively impacted supply chains in the past two years, resulting in shortages in a variety of sectors, including food production, vaccine supply, computer chip manufacturing, and automobile production, according to the paper.
As countries try to move back towards some level of normalization, governments may use VAT data to identify the most vulnerable – and resilient – companies when it comes to supply chains. “It’s impossible for decision-makers to manage economic systemic risks proactively without understanding which companies pose an exceptionally high risk to the entire economy in case of their temporary failure,” the scientists point out.
In the context of current discussions about gas rationing in some EU countries as a consequence of the war in Ukraine, Diem notes that some of the 32 top high-risk companies in the study are in the chemical sector. “These firms, which rely heavily on natural gas for their production, should be – at any cost – protected from gas supply shortages since they will have potentially huge snowball effect on the entire economy.”
About the CSH
The mission of Complexity Science Hub Vienna is to host, educate, and inspire complex systems scientists dedicated to making sense of Big Data to boost science and society. Scientists at the Hub develop methods for the scientific, quantitative, and predictive understanding of complex systems.
The CSH is a joint initiative of AIT Austrian Institute of Technology, Central European University CEU, Danube University Krems, Graz University of Technology, Medical University of Vienna, TU Wien, VetMedUni Vienna, Vienna University of Economics and Business, and Austrian Economic Chambers (WKO).
Researchers from University of Leeds and Cardiff University published a new paper in the Journal of Marketing that examines the nature, functioning, and performance relevance of Machiavellianism in alliance partnerships.
The study, forthcoming in the Journal of Marketing, is titled “Machiavellianism in Alliance Partnerships” and is authored by Giuseppe Musarra, Matthew Robson, and Constantine Katsikeas.
Alliances are an essential component of a firm’s strategic arsenal for thriving in today’s hyper-competitive marketplace. They serve as a mechanism for partners to implement their agendas and achieve marketing-related goals (e.g., develop new product and enter new markets). Yet, many alliances underperform. Given the large investments firms make to form and manage alliances, it is crucial to address such a real-world marketing problem.
A fundamental issue is that both the bright side and dark side of alliances shape their effectiveness. Alliances offer a platform for joint learning that can serve the interests of the partnership (bright side) or they can foster learning-related exploitation and the use of power to prioritize one’s own goals (dark side). The tension between these routes can be used by an alliance partner with Machiavellian characteristics.
“Machiavellianism in an alliance is a firm’s strategy of social conduct that involves manipulation of the partner for own gain, often against its best interests. Our interviews with executives confirm that Machiavellianism resonates strongly in the marketing alliance context,” says Musarra. For example, one CEO commented that “For companies like mine, tie-ups are a unique vehicle that offer great opportunities to benefit from the partner and its skills. We are masters of manipulation.”
Like other social psychology constructs transferred from the individual to the firm level, Machiavellianism is partly dispositional (internal beliefs) and partly manifest (behavioral). The researchers did not find evidence that Machiavellianism is a fixed, firm-level disposition. Instead, the interviewees were convinced their firm’s Machiavellianism and its dimensions (i.e., distrust in the partner, desire for status, amoral manipulation, and desire for control) vary across alliance settings. For instance, the managing director of a marketing alliance was adamant that “It can change. Our motives, needs, and desire to lead in the production of new skills … change, as it is often easier to chalk up another victory by deceiving rather than leading.”
The main study examines a firm’s Machiavellianism as a driver of its performance effectiveness in the alliance via learning and power mechanisms. Machiavellianism harms performance by: (a) weakening motivations to develop and learn new knowledge with the partner (i.e., collaborative learning); (b) strengthening motivations related to anxiety about failing to access and learn new knowledge from the partner (i.e., learning anxiety); and (c) increasing the use of power to dominate the alliance’s agenda.
While Machiavellianism naturally drives learning anxiety, it can encourage collaborative learning when there is situational knowledge furnished by collaborative history. The path to use of power is unaffected by collaborative history. Using history to understand the situation opens the way for Machiavellian pragmatists to favor bright-side (collaborative) learning over the more intuitive dark-side (anxiety) route in the race to learn. Using collaborative history, moderating conditions can benefit performance by neutralizing the negative performance effects of Machiavellianism through collaborative learning and learning anxiety, but not use of power.
The study’s quasi-longitudinal study shows that learning and power effects take time to unfold. Robson says that “Performance outcomes of learning are contingent on the alliance development stage. We observe an inverted U-shaped moderation at the alliance development stage on the paths from collaborative learning and learning anxiety to performance. Once an alliance partnership is past its peak, opportunities fade for both learning-related mechanisms.”
The researchers also observe that the competitive mechanism, use of power, appears to be problematic because it is resistant to the conditioning effects of both knowledge built via collaborative history and the alliance development stage. Machiavellian use of power to dominate the alliance’s agenda is a key concern for alliance management.
“Machiavellian firms’ preoccupation with dark-side learning anxiety and use of power could preclude a focus on collaborative learning, to the detriment of performance. Still, it is important that managers factor into their planning the conditioning effects of alliance situational factors like collaborative history,” advises Katsikeas.
Understanding how to identify a Machiavellian partner is beneficial for practitioners because such partners are adept at creating the illusion of cooperation. The researchers’ interviews uncovered manifestations of Machiavellianism’s behavioral side that would allow the detection of a Machiavellian partner. Machiavellian firms are likely to exhibit behaviors that reflect its dimensions, such as hypervigilance, authoritative work patterns, and calculative adaptations.
Firms may find it prudent to set up an alliance with a partner with Machiavellian characteristics, provided the partner offers a good fit of capabilities for the alliance work. The challenge facing managers is to surface this partner’s Machiavellianism and suppress its deleterious effects until they can find value in collaborative learning.
The Journal of Marketing develops and disseminates knowledge about real-world marketing questions useful to scholars, educators, managers, policy makers, consumers, and other societal stakeholders around the world. Published by the American Marketing Association since its founding in 1936, JM has played a significant role in shaping the content and boundaries of the marketing discipline. Christine Moorman (T. Austin Finch, Sr. Professor of Business Administration at the Fuqua School of Business, Duke University) serves as the current Editor in Chief. http://www.ama.org/jm
About the American Marketing Association (AMA)
As the largest chapter-based marketing association in the world, the AMA is trusted by marketing and sales professionals to help them discover what is coming next in the industry. The AMA has a community of local chapters in more than 70 cities and 350 college campuses throughout North America. The AMA is home to award-winning content, PCM® professional certification, premiere academic journals, and industry-leading training events and conferences. https://www.ama.org