Estuaries, A Happy Place For Fish

Anchovies, salmon, sardines, gobies, mullets, flounder, bass, barbels, eels, shad, and even sharks—what do they have in common? Well, at certain points in their lives you may find them in estuaries, the final sections of rivers before they meet the ocean. Some fish live in estuaries their entire lives. However, some fish species prefer living in the freshwater parts of estuaries, others only live close to the ocean, and a few others spread throughout the estuary. Some species prefer living close to the bottom, some in marshes, and some constantly swim around in the estuary. Some prefer eating other fish, while other species like worms, or insects, or microscopic animals. Unfortunately, many estuarine species are in danger, and all because of humans. In this article, we will tell you why estuaries are such special places for fish and describe some of the species that call the San Francisco Estuary their home.

the Mariana Trench in the Pacific Ocean, at , m deep. Fish living there, like the Mariana snailfish, have the superpower of resisting the freezing temperature and crushing pressure of km of water on top of them. They also live their lives in total darkness [ ].
In the African savannah, you can find the incredible turquoise killifish living in small, shallow pools that form when it rains. Rainwater awakens the eggs that were kept protected in the soil since the previous rainy season. Once awake, the eggs hatch. Their superpower allows the turquoise killifish to hatch from their eggs only when the environmental conditions are perfect [ ].
Fish also have a superpower called osmoregulation [ ]. Like humans,

OSMOREGULATION
The ability to regulate and maintain the right amount of water, nutrients, and salts inside cells.
fish need to keep the right amount of water, salts, and nutrients in their cells. Without this superpower, fish living in the ocean would lose water from their cells and die, because the ocean has much more salt than fish tissues do. Fish living in rivers, called freshwater fish, have the opposite problem. Without osmoregulation, too much water would enter their cells and cause the cells to burst. Usually, fish that live in freshwater cannot use osmoregulation in the ocean, and the other way around. Yet, a few fish species can live in ecosystems where the salinity-the amount of salt in the water-is constantly changing. This is what happens in estuaries. Here, fish species push their osmoregulation superpower to the limit!

TIDES STIR THE SALT IN ESTUARIES
Estuaries are the final sections of rivers before they meet the ocean. Here, the water is brackish, which means that it is not as salty as the ocean, nor as fresh as in rivers. Salinity varies a lot in estuaries because tides mix the water from rivers with water from the ocean [ ]. In most TIDES Tides exist because the moon acts as a magnet causing the rise and fall movement of water in estuaries, coastal lagoons, and along the ocean shores. estuaries, the water is saltier as you get closer to the ocean. During low tide, salinity is at its minimum in the estuary because the water coming HIGH TIDE/LOW TIDE The high tide occurs when one side of the Earth is the closest or furthest away from the moon. The low tide occurs when that side of the planet is in between those points. from rivers pushes estuary water out to the ocean. During high tide, salinity is at its maximum because salty ocean water enters the estuary ( Figure ). Salinity in estuaries may also vary a lot due to weather. If it rains or snows a lot in one season or during a certain year, the estuary will become less salty than usual. But if it does not rain or snow as much as normal, the estuary will become saltier.
Fish living in estuaries must adapt to the constant changes in salinity. Living in estuaries is di cult for fish! Only those species that push their osmoregulation superpower to the limit can live in estuaries. Yet, for these fish, estuaries are a happy place to live [ ]!

ESTUARIES: NURSERIES FOR FISH
Most estuaries around the world are unhealthy because they are surrounded by cities, factories, and harbors. Worldwide, . allow young fish to grow strong and healthy because food is abundant and diverse. The greenish or brownish color of the water makes it di cult for predators to see young fish. In an estuary's streams and marshes, young fish can also find excellent hideouts from big MARSH Shallow aquatic habitat that surrounds estuaries and coastal lagoons. It has vegetation that is adapted to salty water. In tropical regions, mangroves are the equivalent habitat to marshes. predators and refuge from strong currents.
Conditions in estuaries can be so good that fish migrate from the ocean into the estuaries and nearby rivers to reproduce, like the Pacific lamprey in the San Francisco Estuary. Then, larvae and juveniles will grow up there before migrating to the ocean [ ]. This species belongs to a group of migratory fish called anadromous fish [ ]. Other

MIGRATORY FISH
Fishes that need to move between di erent habitats during specific phases of their life to reproduce, feed, grow, and/or find refuge from predators. migratory fish have a di erent strategy, like the American eel. This species migrates to estuaries when they are larvae or juveniles because they can grow faster and stronger than they could in the ocean [ ]. They migrate back to the ocean once it is time to reproduce. The American eel was introduced into the San Francisco Estuary but failed to establish a population. This species belongs to a group of migratory fish called catadromous fish.
Other species even live their entire lives in estuaries, so they are called estuarine residents. This is the case of the tule perch in the San  Figure . kids.frontiersin.org October | Volume | Article |

WHY DO FISH AVOID THEIR NEIGHBORS?
Although it seems there is plenty of space and food in estuaries, along with secret hideouts where fish can hide from predators, each species avoids eating the same kinds of food as other species, and species also avoid living in the same place at the same time [ ]. These behaviors are a brilliant strategy to decrease competition, particularly when food or space becomes scarce.
Scientists can determine how much competition exists between species by studying their ecological niche, which is the fancy

ECOLOGICAL NICHE
Conditions that exist in an ecosystem that allow a species to live. Usually, temperature, salinity, depth, or food preferences are used to describe the ecological niche of fish.
expression for the types of conditions that a species likes [ ]. The ecological niche of a fish includes the water temperature, salinity, or types of sediment it prefers, like sand or mud. The ecological niche may also include the food a species likes. In the San Francisco Estuary, you can find fish that always live in the rivers or the upper part of the Estuary where the water is not salty, such as the Sacramento blackfish.
There are also fish that can live either in freshwater or in the brackish part of the Estuary, like the prickly sculpin. Other species only live in the brackish part of the Estuary, like the cabezon. So, you can deduce that Sacramento blackfish and cabezon will never compete for food or space because they never live in the same place. This means that their ecological niche is completely di erent.
But when species do live in the same place, their ecological niche may overlap. However, fish can still avoid competition. They might eat di erent foods or live at di erent depths. For example, there are benthic species that lay on the bottom most of their lives, pelagic species that are always swimming, and demersal species that live in both places. So, let us examine three species-Northern anchovy, starry flounder, and white croaker-that live in the brackish part of the San Francisco Estuary to see how much competition exists between them ( Figure ). The starry flounder is a benthic species as juveniles and adults, that eats worms, small crabs, and small clams. The Northern anchovy is a pelagic species that only eats zooplankton. So, the ZOOPLANKTON Tiny animals that live in the water. Some resemble miniature shrimp, crabs, or snails, and you need a magnifying lens to see them properly.
competition between starry flounder and Northern anchovy is very low. On the other hand, the white croaker is a demersal species. It spends time swimming around and going down to the bottom to eat clams, crabs, shrimp, or worms. So, the ecological niche of the white croaker and Northern anchovy do not overlap much because they spend only a little time in similar places. However, the competition between starry flounder and white croaker is greater because they like eating similar things that live near the bottom. ecosystems, or of the winter-run Chinook salmon, which only spend a few weeks in the Estuary at the most. These species are in danger from water pollution, overfishing, invasive species, destruction of marshes and shorelines, dams, and climate change-the same reasons that many fish species all over the world are in danger.

PROTECTING FISH IN ESTUARIES AND ELSEWHERE
Protecting fish and other wildlife may seem, at times, a lost cause. But people are becoming more mindful of the environment. More and more people avoid wasting good water in their homes. Others work to establish agricultural practices that do not use pesticides or fertilizers that can harm the environment. Other people choose to use clean, renewable energy in their homes, and some deliver dangerous chemicals to recycling centers instead of pouring them down the drain.
If you want to protect fish and other wildlife, you can start by sharing this article with your family, friends, and teachers. Make a list of your ideas about how to protect the animals and plants from your region. Find people with the same goals. Write or talk with the mayor of your city or village. Let everyone know that a healthy environment is important for all living creatures on the planet and that we need to protect them before it is too late. . Fichman, R. A., Khen, A., Willmes, M., Kuntz, J., Scott, A. R., Hobbs, J.A., et al. . . doi: . /frym. .

CONFLICT OF INTEREST:
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
COPYRIGHT © Morais and Dias. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

YOUNG REVIEWER
FRESIA, AGE: I love science and math, but I am not a fan of history and geography. My big passion is animals. I have a snake named Sacha jr. and a rabbit named Luna, and I love to raise silkworms and search for lizards and other animals in the wild. I am also learning to ride horses and I love using creativity to make crafts.

PEDRO MORAIS
My passion for marine biology began when I was years old. I went on vacation with my parents and sister to a lovely beach in southern Portugal. There, I spent all the time I could in the tide pools searching for fishes, crabs, shrimps, and anemones. I have studied all kinds of aquatic organisms (bacteria, microscopic algae, jellyfish, clams, crabs, birds, fish, and even whales and dolphins) from the deep ocean to shallow lagoons, estuaries, rivers, lakes, and streams. During my free time, I enjoy dancing tango, taking photographs, woodworking, fixing and restoring old things, and researching my ancestry. *pmorais@ualg.pt kids.frontiersin.org October | Volume | Article | ESTER DIAS I am a researcher at the Estuarine Ecology and Biological Invasions research group (CIIMAR-University of Porto, Portugal). As a child, I was curious about how animals behave, what they eat, and why they need to migrate long distances to reproduce. So, becoming a biologist was my chance to find the answer to these questions. So far, I have studied small aquatic animals called zooplankton (some only mm in size), clams, aquatic birds, fish, and even marine mammals. Currently, I study the migrations of fish, the impacts of biological invasions, and what is on the menu of each aquatic species.