Sleep tight, don’t let the bed bugs bite!

Have you ever felt uncomfortable when hearing this expression or feared to find your bed infested with bed bugs? Yes, bed bugs exist. However, good news is that not all insects known as ‘bugs’ sting nor live inside our bed sheets.

What bugs really are? Are all of them harmful? Where can we find them? Find out their diversity through this post, and give up thinking that bugs are dangerous!

Which insects are called ‘bugs’?

When talking about ‘bugs’, people are unconscious about the true diversity of these organisms. Bugs, and more exactly true bugs, belong to the Heteroptera suborder, which includes more than 40,000 species worldwide; in fact, they are the largest group of insects with simple metamorphosis. Their most ancient fossil, Paraknightia magnífica, which was found in Australia, has been dated from the late Permian (260-251 MA).

The Heteroptera belong to the Hemiptera order, inside which we can find other suborders which were formerly classified as a single suborder (‘Homoptera’). Some of the suborders once classified as ‘Homoptera’ include some well-known organisms, such as cicadas (Cicadidae) and aphids (Aphididae).

How can we recognize them?

Heteropterans appear in different forms and sizes. The tiniest specimens belong to the Anthocoridae, Microphysidae, Ceratocombidae, Dipsocoridae, Aepophilidae and Leptopodidae families, which are barely visible to the naked eye. Among the largest members there are some species of the Belostomatidae family, such as Lethocerus indicus (6.5-8 cm length). Despite this, they appear as a monophyletic group according to molecular data.

They show at least three synapomorphies:

1. Piercing-sucking mouthparts, long, forming a stylet.

   

   Mouthparts of the predator Arilus cristatus (Reduviidae). Picture property of John Flannery on Flicker (CC 2.0).

2. Paired odoriferous glands.
3. Four-segmented antennae.

Furthermore, they have forewings (formally known as hemelytra) with both membranous and hardened portions, which gives its name to the group (Heteroptera, from the Ancient Greek ‘hetero’, different; ‘-pteron’, wings).

Pentatomidae. The proximal part of forewings is hardened, while the distal one is membranous. Picture property of Mick Talbot on Flickr (CC 2.0).

Ecology

Life cycle

Heteropterans undergo a simple metamorphosis, so youths or nymphs and adults almost show no differences and cohabit in the same habitat. After hatching, nymphs molt several times until reaching the last nymphal molt, known as imaginal molt, through which they reach adulthood.

Life cycle of heteropterans. Picture property of Encyclopedia Britannica, Inc. (link).

Adults differ from nymphs on having wings, a new disposition of odoriferous glands openings, a different number of tarsal (legs) and antennal segments, ocelli, ornaments (spines and glandular hairs), sexual traits on the terminal abdominal segments and sometimes a different coloration, besides a bigger size and a way harder tegument.

Nezara viridula nymph (Pentatomidae), still wingless. Picture property of S. Rae on Flickr (CC 2.0)

Communication and defense

Specimens of the same species emit volatile pheromones produced by their odoriferous glands as a way of communication. So, they can expel aggregation pheromones and sexual pheromones to gather in a point or to find a mate, respectively. In some species, it has also been documented the emission of sounds produced by stridulation, that is, producing sounds by rubbing together certain body parts.

Heteropterans develop passive and active defense mechanisms:

• Among passive mechanisms, we can highlight the own body shapes (e. g., smooth and rounded structures which difficult their capture by predators), the inactivity as a way to go unnoticed by other organisms, and the crypsis or mimicry. Some examples of crypsis or mimicry are 1) color mimesis (homocromy) 2) shape mimesis (homotopy), through which they imitate structures of their environment, either plants or animals (e. g. ant-mimicry or myrmecomorphy) and 3) disruptive mimesis, that is, their outlines get blurred with the environment, so it gets difficult for predators to find them.

Leptoglossus occidentalis (Coreidae), with their wide tibiae that look like leaves. Picture property of Giancarlodessi (CC 3.0).

Myrmecoris gracilis (Miridae), a clear example of ant-mimicry or myrmecomorphy. Picture property of Michael F. Schönitzer (CC 4.0).

• Some active mechanisms are 1) escaping, 2) biting, 3) the detachment of some appendices to confuse predators and 4) the emission of stink or irritating substances by their odoriferous glands, which in most of cases they acquire from plants they feed on. Others emit stridulating sounds.

Life forms and diversity

Even though most people know something about heteropterans due to the famous bed bugs, feeding on blood is far from being the only life form among true bugs.

• Terrestrial

Most heteropterans inhabit terrestrial environments, either on plants or on the ground as phytophagous (they feed on vegetal fluids) or predators of other insects. There are also some terrestrial heteropterans that feed on roots or on fungi that develop under tree bark. Some examples of terrestrial phytophagous families are Pentatomidae and Coreidae. Among predators, which use their stylet to inoculate proteolytic agents inside their preys to dissolve their content and then suck it, there are a lot of members from Reduviidae family.

• Aquatic and semiaquatic

Aquatic and semiaquatic forms have special adaptations to live in water, like hydrofuge hairpiles which repel the water. Most of them live in lakes and rivers, either on their surface (semiaquatic) or submerged.

Semiaquatic species usually have long legs and long antennae, which together with the hydrofuge hairpiles let them to stand on water. Water striders (Gerridae), which are very abundant in Europe, are a clear example of this life form.

Water striders (Gerris sp.). Picture property of Webrunner (CC 3.0)

Aquatic species usually have a pair of legs adapted to swim. A good example of this are the members of the family Notonectidae or backswimmers, which have the hind legs fringed for swimming.

Notonecta sp. (Notonectidae). Picture property of Jane Burton/Bruce Coleman Ltd. (link).

Despite living in water, aquatic heteropterans need surface air to breath, so they go out of water periodically. They present different strategies to absorb oxygen, such as swallowing air that goes directly to the respiratory or tracheal system through a siphon (Nepidae) or capturing air bubbles with their hydrofuge hairpiles (Nepidae). Other simply get covered of a tiny air layer using their hydrofuge hairpiles.

• Hematophagous

Finally, there are heteropterans that feed on blood and live as bird and mammal parasites. This is the case of the Cimicidae family (e. g. Cimex lectularius, the bed bug) and some groups of Reduviidae, such as the members of the subfamily Triatominae, which are also known for being vectors of the Chagas disease in the center and south of America (being Triatoma infestans its main vector).

Cimex lectularius or bed bug nymph. Public domain.

Triatoma sp. (Triatominae). Picture property of Bramadi Arya (CC 4.0).

Scientific interest

• They help to regulate some wood and crop pests, having an important role in integratative pest management. This is the case of some predator heteropterans from the Reduviidae, Anthocoridae, Miridae, Nabidae and Geocoridae families. However, some phytophagous heteropterans can act as pests too.
• They have been an interesting scientific model for the study of insect physiology.
• They are an important element on human diet in some countries, being Pentatomidae one of the most consumed families. Some aquatic heteropterans, such as Lethocerus sp. (Belostomatidae) are very appreciated as food in some Asiatic countries, like Vietnam and Thailand.

Lethocerus sp. Picture property of Judy Gallagher on Flickr (CC 2.0).

• Some of them are disease vectors or a cause of discomfort. The most classic example is the bed bug (Cimex lectularius), which has become a frequent pest in temperate regions; some Cimidae are also a threat for free range chickens and other farm birds. In America, Triatominae are vectors of different diseases, being the most famous the Chagas disease (transmitted by a protozoan, Trypanosoma cruzi).

.                .                 .

All organisms on Earth are necessary for some reason: you only need to investigate about them. Even the true bugs!

References

• Goula M., Mata L. 2015. Orden Hemiptera: Suborden Heteroptera. Revista IDE@ – SEA, 53: 1–30.
• https://www.britannica.com/animal/heteropteran
• Schuh R. T., Slater J. A. 1995. True Bugs of the World (Hemiptera:Heteroptera): Classification and Natural History. Cornell University Press.

Main picture property of Pavel Kirillov on Flickr, with license  Creative Commons 2.0. (link).

Disease outbreaks, another effect of climate change?

We know that many infectious diseases depend on climatic factors such as temperature. So, can climate change cause an increase of the outbreaks? Let’s find out!

HEALTH AND CLIMATE CHANGE

 According to some surveys conducted by the Pew Research center, 54% of respondents believe that climate change is a serious problem and their major concerns include drought, intense rainfall and heat. If you are interested in to learn more about this survey, you can find them in the following article.

These changes have a negative effect on human health. The World Health Organization (WHO) expected that between 2030 and 2050 climate change will cause some 250,000 additional deaths a year. The effects can be very varied: deaths by  heat, floods, increase in respiratory diseases, stress etc. One of the important health effects is an increase in the transmission of infectious diseases.

Graphic of impacts of climate change on human health (Photo: CDC)

Infectious diseases are closely related to  environment’s characteristics (such as temperature and humidity). In some cases, these diseases are transmitted by vectors (bats, arthropods, snails, rodents, ticks…). A  temperaturerising  will modified its geographical distribution, seasonality and population size. An example is  the presence of the mosquito Aedes albopictus, known as mosquito tigre, in Spain.

On the other hand, changes in the use of the soil, overcrowding of cities, poor hygienic habits and other socio-economic factors also have an effect in the transmission of certain diseases. For example, deforestation and poor hygiene of the population increases the breeding sites of the mosquitoes, causing an increase in the probability of malaria transmission.

Human activities may effect diseases transmission rate. (Photo: OMS)

VECTOR DISEASES

Vector diseases are those that are transmitted through a vector animal (whether a mosquito, rodent, tick, snail, bat…). These diseases may be zoonotic (animal to human, as rabies) or antroponotic (among humans, such as malaria or dengue). If you want to know more about the effects of climate change on vector, feel free to access this article.

Different types of vector diseases. (Photo: OMS)

There are many vector diseases which should be monitored in the coming years, as for example the malaria, dengue fever chikungunya, Boutonneuse etc. Let’s look at the two best known infectious diseases.

MALARIA

This disease is caused by parasites of the genus Plasmodium, which is transmitted by the bite of mosquitoes of the genus Anopheles. There are four different types of malaria, but the most deadly is that caused by the species Plasmodium falciparum.

Plasmodium falciparum gametocyte. (Photo: CDC)

The WHO estimates that in the year 2013, 198 million people were infected,  584,000 of which died. It is expected that these numbers will increase due to climate change. Temperature rise leads to an increase in the infective period of the mosquito and the modification of vector’s geographical distribution. Possibly in the next few years, if the trend does not change, there will be an increase in the spread of the disease in endemic areas  and will probably resurface in other areas (red areas on the map).

Estimation of the spread of malaria in 2050 (Photo: Randolph Rogers)

In Spain, the autochthonous malaria was eradicated in 1964. Currently, the spanish cases of malaria are imported from countries with indigenous malaria. Even so, note the geographic situation of our country, the rising temperatures, the presence of a competent vector and the presence of imported parasit, significantly increase the likelihood of disease’s transmission.

DENGUE FEVER

This is a viral disease (caused by viruses of the genus Flavivirus) that is transmitted by the bite of mosquitoes of the Aedes genus (including the Tiger mosquito). Dengue fever is a widespread disease in tropical countries, although its suffering geographical changes due to changes in temperature, precipitation and a demographic overcrowding of the cities.

Structure of dengue fever virus (Photo: César Cabezas)

Before 1970, only nine countries had experienced serious dengue epidemic episodes. In recent decades, the cases have increased sharply. According to WHO estimates, each yerar are produced about 390 million infections,  23%  of which are clinically manifested.

forecast of the spread of dengue fever in Europe during the twenty-first century. Expressed in nº of cases /100.000 habitants. (Photo: Moha Bouzid)

As in the case of malaria, current climatic variations alter the geographical distribution of the vector. As we can see in the previous map, the predictions for this century, if conditions do not change, are a significant dengue fever cases increase in Northern Europe (lighter areas are potential sites of infection). As we see in the case of Spain, the Mediterranean would be the region that would have more cases of dengue fever.

WATERBORNE DISEASES

Climate change also affects the water cycle. The news about weather disasters (floods, strong drought, torrential rains, hurricanes…) never cease to appear in the media. These climatic variations affect those diseases that are spread by water, either by contamination of the flows, by human migration and low hygiene that exist in certain places of overcrowded cities.

The most known diseases associated with floods and droughts are infections of Cryptosporidium or cholera. Let’s look at this last example.

CHOLERA

Vibrio cholerae is a bacilar bacteria that causes this disease. It is a diarrheal infection that suffer every year between 1.4 and 4.3 million people, 142,000 which end up dying. The transmission of this Bacillus is closely linked to environmental mismanagement. Heavy rains or flooding can cause water pollution, and extreme drought increases the bacterial charge of the existing flows.

Microphoto of Vibrio cholerae (Photo: Louisa Howard).

During the 19th century, cholera spread across the world from Ganges (India). The last cholera epidemic began, as we can see in the map, in the South of Asia in 1961. Now cholera has been distributed worldwide due above all to human migrations (bacillus carriers), the agglomeration of people in suburban areas without hygiene habits and climate disasters. The WHO estimates that by 2030 there will be 10% more cases due to climate change.

evolution of last epidemic of cholera (1961-2004). (Photo: IPCC)

It may not be possible to quantify in that measure climate change can affect the transmission of these diseases, since these depend on many other factors (demographic dynamics, immunization, etc.). Is worth mentioning, that the provisions set out in this article are assumptions obtained from current data. That means, that if the mechanisms for the reduction of global climate change works and environmental conditions improve, these data would no longer have any statistical value

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Remember that it is better to be safe than sorry!

Cares for the environment: the Earth is your home. 

REFERENCES

• World Health Organization (WHO)
• Center of disease control (CDC)
• Observatory of health and changing climate (Ministry of health) (Spanish)
  • Impacts of climate change on health . PDF (Spanish)
• Cover Photo: Lucía Nodal, Solo kilovatios verdes.